Showing total 540 results

201. DC Capacitor Voltage Balancing Control for Delta-Connected Cascaded H-Bridge STATCOM Considering Unbalanced Grid and Load Conditions.

Author

Jung, Jae-Jung, Lee, Joon-Hee, Sul, Seung-Ki, Son, Gum Tae, and Chung, Yong-Ho

Subjects

*CONVERTERS (Electronics), *SYNCHRONOUS capacitors, *CAPACITORS, *COMPUTER simulation, *VOLTAGE control, *MICROGRIDS, *ELECTRICAL load

Abstract

In this paper, a comprehensive control scheme for a delta-connected cascaded H-bridge (CHB) converter-based static synchronous compensator (STATCOM) is presented, especially focusing on improving dynamic performance by novel feedforward control method. The method can conspicuously improve the dynamics of zero-sequence circulating current regulation of delta-connected CHB STATCOM especially under grid fault condition as well as load unbalance without excessive dc cell capacitor voltage fluctuation. The validity of the proposed method is demonstrated by mathematical proof. Finally, the full-scaled simulation results and the down-scaled experimental results verify that stable operation is guaranteed for both emulated grid and load unbalance conditions. [ABSTRACT FROM AUTHOR]

Published

2018

202. Topology and Control of a Five-Level Hybrid-Clamped Converter for Medium-Voltage High-Power Conversions.

Author

Wang, Kui, Zheng, Zedong, Xu, Lie, and Li, Yongdong

Subjects

*ELECTRIC network topology, *CONVERTERS (Electronics), *CAPACITORS, *PULSE width modulation, *VOLTAGE control

Abstract

Five-level hybrid-clamped (5L-HC) converter is a newly proposed topology which is suitable for high-performance medium-voltage high-power conversions without switches directly connected in series. The critical issue of this converter is that two flying capacitor voltages of each phase and two neutral-point potentials of the dc-link need to be balanced. This paper presents a decoupled voltage balancing method for this 5L-HC converter based on modified phase-shifted pulse width modulation (PS-PWM) and optimal zero-sequence voltage injection. The voltages across the central dc-link capacitor and two flying capacitors are balanced first by adjusting the width of four PWM signals. Second, the relationship between the neutral-point currents and the output phase voltage is studied and the upper and lower dc-link capacitor voltages are balanced by zero-sequence voltage injection. Both steady-state and dynamic-state simulation and experimental results are presented to confirm the validity of this method. [ABSTRACT FROM AUTHOR]

Published

2018

203. A Novel Reversal Coupled Inductor High-Conversion-Ratio Bidirectional DC?DC Converter.

Author

Liu, Hongchen, Wang, Liuchao, Ji, Yuliang, and Li, Fei

Subjects

*ELECTRIC inductors, *DC-to-DC converters, *VOLTAGE control, *ENERGY transfer, *CAPACITORS

Abstract

A novel high-conversion-ratio bidirectional dc–dc converter with coupled inductor is proposed in this paper. Compared with the bidirectional converters based on coupled inductor, this new topology can realize a higher step-up voltage gain and lower step-down voltage gain with a lower turn ratio in an appropriate duty cycle. In proposed converter, the windings of the coupled inductor are reversely connected to transfer energy from high voltage source or low voltage source. Then, a clamp capacitor is applied to reduce voltage stress on main switch; therefore, the conduction loss of the main switches can be reduced by using a low resistance switch, and the clamp capacitor can also recycle the energy of the leakage inductor in coupled inductor. Besides, the soft-switching technique is used to achieve zero voltage switching, so the efficiency can be further improved. The main circuit and its steady-state operating principle are analyzed in detail. Finally, a 25–200 V 200 W bidirectional dc–dc converter is implemented to verify its performance. [ABSTRACT FROM AUTHOR]

Published

2018

204. PWM Control Scheme for a Buck/Boost Modular Multilevel DC/DC Converter With Reduced Submodule Capacitance.

Author

Xing, Zhongwei, Ruan, Xinbo, and Xie, Huanmao

Subjects

*PULSE width modulation, *DC-to-DC converters, *HIGH voltages, *DIRECT currents, *ELECTRIC power distribution grids, *ELECTRIC lines, *ELECTRIC capacity

Abstract

High-voltage direct current (HVdc) grid which incorporates multiple dc transmission lines will have extensive application since it has better operating flexibility and enhances the power trade. DC/DC converters are important components in the HVdc grid. The buck/boost modular multilevel dc/dc converter (MMDCC), which uses half-bridge submodules to reduce the voltage stresses across the power switches, is a good choice for the nonisolated applications in the HVdc grid. This paper proposes a pulse width modulation (PWM) control scheme for the buck/boost MMDCC, which uses much smaller submodule capacitors than those in the existing phase-shifted (PS) control scheme, thus reducing the converter volume and weight significantly. The operating principle of the proposed PWM control scheme is elaborated, along with the submodule capacitor voltage balancing strategy and the closed-loop control flowchart. Besides, the capacitance requirement of the buck/boost MMDCC in the PWM control scheme is calculated and compared to that in the PS control scheme, showing a dramatic reduction. The reason for the capacitance requirement difference of the two schemes is also explained. Simulation and experimental results validate the effectiveness of the proposed PWM control scheme and its ability to reduce the submodule capacitance. [ABSTRACT FROM AUTHOR]

Published

2018

205. A New Dual-Bridge Series Resonant DC–DC Converter With Dual Tank.

Author

Wu, Junjuan, Li, Yuci, Sun, Xiaofeng, and Liu, Feilong

Subjects

*DC-to-DC converters, *POWER transformers, *ELECTRIC circuits, *SWITCHING circuits, *VOLTAGE control

Abstract

Compared to the dual-active-bridge converter, the dual-bridge series resonant converter (DBSRC) can widen soft-switching range. To further widen the soft-switching range and improve the circuit performance, a new DBSRC with dual tank based on DBSRC is proposed in this paper. This new converter features two resonant tanks and a tapped transformer, and it can perform better than the DBSRC by optimized tap coefficient x of the tapped transformer. Its operation principle, voltage gain, the soft-switching characteristics, and output power are analyzed in detail, and compared with the DBSRC. Results show that the proposed dual-tank topology has presented higher voltage gain, wider soft-switching region, and larger output power than the traditional DBSRC when the tap-coefficient x is selected reasonably. At last, a 1-kW prototype is built; experimental results verify the feasibility and advantages of the proposed dual-tank converter. [ABSTRACT FROM PUBLISHER]

Published

2018

206. Commutation Torque Ripple Suppression Strategy for Brushless DC Motors With a Novel Noninductive Boost Front End.

Author

Jiang, Guokai, Xia, Changliang, Chen, Wei, Shi, Tingna, Li, Xinmin, and Cao, Yanfei

Subjects

*BRUSHLESS direct current electric motors, *TORQUE, *CAPACITORS, *METAL oxide semiconductor field-effect transistors, *VOLTAGE control, *STATORS, *ELECTRIC inductance

Abstract

This paper first presents a novel boost front end simply with a diode, a MOSFET, and a DC-link capacitor. Without extra inductors or other power components, the boost font end could boost the capacitor voltage with the motor stator inductances, thus reducing the influence of the limited DC-link voltage on commutation torque ripple reduction to a large extent. A unified commutation torque ripple suppression strategy is further proposed with the front end adopted based on the analysis about the effects of four switching vectors on motor speed regulation and DC-link capacitor voltage regulation. The proposed strategy can boost the DC-link capacitor voltage via properly selection of switching vectors under the premise of guaranteeing normal speed regulation in noncommutation period, and reduce both the commutation torque ripple and commutation time by two consistent switching vectors with the boosted DC-link capacitor voltage in commutation period. Finally, the proposed method is theoretically analyzed with respect to the capacitance selection and the boot capacity of noninductive boost front end. The correctness of the analysis and the effectiveness of the presented method are validated by the experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

207. Influences on Output Distortion in Voltage Source Inverter Caused by Power Devices? Parasitic Capacitance.

Author

Wang, Dafang, Zhang, Peng, Jin, Yi, Wang, Miaoran, Liu, Gang, and Wang, Mingyu

Subjects

*IDEAL sources (Electric circuits), *PULSE width modulation, *ELECTRIC distortion, *CAPACITORS, *VOLTAGE control

Abstract

Insertion of dead time in space vector pulse width modulation (SVPWM) causes phase voltage and current distortion or even zero-current clamping phenomenon, degrading the control performance of ac induction motor. In addition, analysis of distortion becomes more complicated due to the existence of parasitic capacitance in power switching device of voltage source inverter (VSI). This paper tries to make clear that how the parasitic capacitance influences VSI's output independently. First, an equivalent circuit of VSI containing parasitic capacitance is constructed. On that basis, mathematical expression of phase voltage distortion is derived from Kirchhoff's voltage law, Kirchhoff's current law, and charge and discharge characteristics of capacitance. Moreover, through the division of multiple zero-crossing regions in one phase current period, the difficulty of obtaining specific phase voltage error expressions is overcome. Second, to figure out the effect of parasitic capacitance, it is theoretically discussed in detail that how parasitic capacitances of different values affect phase voltage, current distortion, and zero-current clamping phenomenon. At last, simulations and experiments are carried out in which VSI with different parasitic capacitances is constructed by paralleling additional capacitors and with phase voltage feedback methods, the theoretical analysis can be verified. [ABSTRACT FROM PUBLISHER]

Published

2018

208. A Single-Switch Quadratic Buck?Boost Converter With Continuous Input Port Current and Continuous Output Port Current.

Author

Zhang, Neng, Zhang, Guidong, See, Khay Wai, and Zhang, Bo

Subjects

*CONVERTERS (Electronics), *ELECTRIC inverters, *VOLTAGE control, *ELECTRIC power conversion, *CAPACITORS

Abstract

A single-switch quadratic buck–boost converter with continuous input port current and continuous output port current is proposed in this paper. Compared with the traditional buck-boost converter, the proposed converter can obtain a wider range of the voltage conversion ratio with the same duty cycle. Moreover, the proposed converter can operate with continuous input port current and continuous output port current compared to the existing counterparts with inherently discontinuous input port current and discontinuous output port current. The operating principle and steady-state performance of the proposed converter under continuous inductor current mode is analyzed in detail. Then, the comparison between the proposed converter and the existing quadratic buck–boost converters has been conducted to demonstrate the unique features of the proposed one. Finally, experimental results from a prototype built in the lab are recorded to verify the effectiveness and validity of the proposed quadratic buck–boost converter. [ABSTRACT FROM PUBLISHER]

Published

2018

209. PWM Control Scheme For Quasi-Switched-Boost Inverter to Improve Modulation Index.

Author

Nguyen, Minh-Khai and Choi, Youn-Ok

Subjects

*PULSE width modulation, *ELECTRIC inverters, *CAPACITORS, *VOLTAGE control, *ELECTRIC inductors

Abstract

The simple boost control (SBC) method is usually used to control the shoot-through state in a single-phase single-stage quasi-switched boost inverter (qSBI). This paper proposes a new pulse-width modulation (PWM) control scheme to improve the modulation index for the qSBI. The advantages of the proposed method for the qSBI over the conventional SBC method are as follows: 1) the modulation index is larger; 2) the voltage stress on the capacitor, diodes, and switches is reduced significantly; 3) the high-frequency peak-to-peak inductor current and capacitor voltage ripples are smaller; 4) the shoot-through current is lower; and 5) the efficiency is higher. The operating principles and circuit analysis for the proposed PWM control scheme are shown. To verify the performance of the proposed PWM control method, a 400W prototype was built with a 110 V/50 Hz output voltage. The experimental results matched those of the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2018

210. A Simplified PWM Strategy for Three-Level Converters on Three-Phase Four-Wire Active Power Filter.

Author

Li, Fei, He, Fengyou, Ye, Zongbin, Fernando, Tyrone, Wang, Xiaojie, and Zhang, Xulong

Subjects

*PULSE width modulation, *CONVERTERS (Electronics), *ELECTRIC power filters, *VOLTAGE control, *CAPACITORS

Abstract

Presently, the neutral-point potential offset is an inherent problem for three-level converters on three-phase four-wire active power filters. The conventional three-dimensional space vector pulse width modulation (3-D-SVPWM) strategy is adopted as a normal solution to the problem, but the selection of space vector sectors for four-wire converter is both abstract and complicated in practice. This paper proposes a new PWM strategy accordingly to simplify the selection process and the calculation of duration. Compared to the conventional 3D-SVPWM, the proposed method locates the sector of optimal vector directly with the polarity of three-phase reference voltage. Then, by applying voltage–second balance rule, it can perform a fast calculation of the duration and generate PWM signals to control the switching devices’ on/off. As an approach to correct the imbalance dc-link capacitor voltage, this strategy reconstructs the switching sequence. A portion of state O duration is disassembled into states P and N to suppress the neutral-point potential offset. The proposed strategy is validated with a range of experiments. The results indicate that this simplified PWM strategy can effectively reduce the computational burden, and also the dc-link capacitor voltage is well controlled. [ABSTRACT FROM PUBLISHER]

Published

2018

211. Modular Multilevel Converter Control Strategy Based on Arm Current Control Under Unbalanced Grid Condition.

Author

Ou, Zhujian, Wang, Guangzhu, and Zhang, Lanhua

Subjects

*CONVERTERS (Electronics), *MICROGRIDS, *CAPACITORS, *VOLTAGE control, *ELECTRIC filters, *COORDINATE transformations

Abstract

The existing control strategies of modular multilevel converter (MMC) balance the capacitor voltage on the premise that the active power of ac side is balanced with that of dc bus. Thus, the symmetrical ac-side current references and the unevenly distributed dc current references in three legs are obtained by coordinate transformation, precise calculation, and numerous filters under unbalanced grid condition. However, by controlling capacitor voltages, the active powers between ac side and dc bus can self-regulate to balance, and this could simplify the obtainment of ac-side current references and dc-bus current references. Based on this idea, this paper proposed a control strategy, which combines the multi-hierarchy control with the arm current control for MMC under unbalanced grid condition. Within the multi-hierarchy control, the symmetrical ac-side current references and the unevenly distributed dc current references in three legs could be obtained easily by three voltage controllers in the abc coordinate, avoiding coordinate transformation, precise calculation, and numerous filters in the existing methods. Besides, the employment of the arm current control removes the need of the three-sequence ac-side current controllers and the three-sequence circulating current suppressing controllers. The proportional regulator with a feedforward steady-state duty cycle is designed for arm current regulator, which can perfectly track its reference and is easy to design, avoiding the complicated design of proportional resonant (PR) controllers. Both system-level simulation results and low-level experiment results verify the feasibility and effectiveness of proposed strategy. [ABSTRACT FROM PUBLISHER]

Published

2018

212. Independent Control of Multicolor-Multistring LED Lighting Systems With Fully Switched-Capacitor-Controlled $LCC$ Resonant Network.

Author

Wong, C. S., Loo, K. H., Iu, Herbert Ho-Ching, Lai, Y. M., Chow, Martin H. L., and Tse, Chi K.

Subjects

*LED lighting, *CAPACITOR switching, *SPECTRUM analysis, *PROBLEM solving, *CURRENT balances (Electric meters)

Abstract

Current imbalance is a major problem in multistring LED lighting systems. Significant research efforts have been directed to solve the problem by either an active or passive approach. However, in view of some system requirements or other emerging lighting applications, independent control of different LED strings is getting more important to obtain different desirable brightness and/or color spectrums. The existing active and passive approaches have their limitations to perform current balancing and independent control simultaneously, thus posing another great challenge for the design of LED drivers. In this paper, a fully switched-capacitor-controlled $LCC$ resonant converter is designed to address this challenge. With the replacement of all fixed capacitors in the resonant tank of the $LCC$ converter with switch-controlled capacitors (SCCs), the regulation of the common ac bus voltage, current balancing, and individual current control of LED strings can be readily achieved with a single LED driver by varying the effective capacitances of the SCCs under constant switching frequency. In this way, the circuit complexity can be greatly reduced while the circuit performances can be significantly improved. An experimental prototype of driving LED growth light for indoor farming applications is designed and constructed to verify the idea. [ABSTRACT FROM PUBLISHER]

Published

2018

213. A Single Phase AC/DC/AC Converter With Unified Ripple Power Decoupling.

Author

Liu, Yonglu, Sun, Yao, Su, Mei, Li, Xing, and Ning, Sijie

Subjects

*AC DC transformers, *ENERGY storage, *VOLTAGE control, *BRIDGE circuits, *CAPACITORS, *IDEAL sources (Electric circuits)

Abstract

In single phase ac/dc/ac converters, the low frequency ripple powers exist both at the source and load sides. Usually, large dc-link filter components are used to buffer the ripple powers, which increases volume and weight. To overcome the drawback, this paper presents a single phase ac/dc/ac current source converter with unified ripple power decoupling. The converter only consists of three bridge arms and a decoupling circuit. The three bridge arms play the role of rectification and inversion with sharing a bridge arm. And the decoupling circuit is in series with the dc-link energy storage unit to buffer the ripple powers. The circuit configuration and operation principles are introduced first. Then, a modulation strategy based on Cartesian space is developed to achieve sinusoidal input and output currents. The control idea that the dc-link current is regulated by the decoupling circuit and the averaged decoupling capacitor voltage is maintained by the rectifier is adopted. The ripple power buffer is automatically achieved. Finally, the theoretical analysis is favorably verified by the simulations and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

214. A Capacitor Voltage Balancing Method for a Modular Multilevel DC Transformer for DC Distribution System.

Author

Shao, Shuai, Jiang, Mingming, Zhang, Junming, and Wu, Xinke

Subjects

*DC transformers, *CAPACITORS, *ELECTRIC potential, *HIGH voltages, *FAULT tolerance (Engineering), *VOLTAGE control

Abstract

A capacitor voltage balancing method for a modular multilevel dc (MMDC) converter is proposed. The MMDC inherits the desirable features of both a modular multilevel converter (MMC) and a dual active bridge, namely high voltage capability, fault tolerance, zero-voltage switching-on of all the power devices, and a wide operating range. These features are ideal for a dc transformer in any dc distribution system. One key MMDC control issue is balancing of submodule capacitor voltages. Conventional MMC balancing techniques cannot be used as arm currents of an MMDC change direction within each switching cycle. This paper establishes that the average capacitor voltage of each arm is self-balanced and proposes a method to balance voltages within an arm by assigning the gate signals with higher charge difference to the submodules with lower voltages and vice versa. Charge difference is obtained by the voltage difference, hence only the SM capacitor voltages are required for balancing control. Different from the existed methods, the proposed technique is not limited by voltage gain or load conditions. Simulation and experimental results show that capacitor voltages are balanced under different voltage gains, different output power, and also when the MMDC starts up, hence ensuring the stable MMDC operation. [ABSTRACT FROM PUBLISHER]

Published

2018

215. An Adaptive Voltage-Balancing Method for High-Power Modular Multilevel Converters.

Author

Luo, Yongjie, Li, Zixin, Xu, Luona, Xiong, Xiaofu, Li, Yaohua, and Zhao, Cong

Subjects

*CAPACITOR switching, *CONVERTERS (Electronics), *CAPACITORS, *VOLTAGE control, *ELECTRIC potential

Abstract

The voltage balancing of the floating capacitors in modular multilevel converter (MMC) is of great importance for the safe operation. However, the existing voltage-balancing algorithms usually suffer from high switching frequency, leading to unnecessary switching losses and device costs. This paper proposes an adaptive capacitor voltage-balancing method for high-power MMCs with reduced switching frequency. The operational characteristics and switching process of the submodules (SMs) are analyzed in detail. And then the relationship between the switching frequency and the capacitor voltage deviation is derived. Based on the analysis, an adaptive method is proposed to make a trade-off between the switching losses and the balancing effect through a closed-loop control of the alternating number of the SMs. The calculation formulas of the switching frequency are also presented. PSCAD/EMTDC simulation and RT-LAB-based real-time control hardware in the loop (HIL) test results demonstrate the effectiveness of the proposed method under different operating conditions. [ABSTRACT FROM PUBLISHER]

Published

2018

216. Single-Phase Boost Inverter-Based Electric Vehicle Charger With Integrated Vehicle to Grid Reactive Power Compensation.

Author

Wickramasinghe Abeywardana, Damith Buddika, Acuna, Pablo, Hredzak, Branislav, Aguilera, Ricardo P., and Agelidis, Vassilios G.

Subjects

*REACTIVE power, *ELECTRIC vehicles, *ELECTRIC power distribution grids, *WAGES, *VOLTAGE control, *PLUG-in hybrid electric vehicles

Abstract

Vehicle to grid (V2G) reactive power compensation using electric vehicle (EV) onboard chargers helps to ensure grid power quality by achieving unity power factor operation. However, the use of EVs for V2G reactive power compensation increases the second-order harmonic ripple current component at the DC-side of the charger. For single-phase, single-stage EV chargers, the ripple current component has to be supplied by the EV battery, unless a ripple compensation method is employed. Additionally, continuous usage of EV chargers for reactive power compensation, when the EV battery is not charging from the grid, exposes the EV battery to these undesirable ripple current components for a longer period and discharges the battery due to power conversion losses. This paper presents a way to provide V2G reactive power compensation through a boost inverter-based single stage EV charger and a DC-side capacitor without adversely affecting the EV battery. The operation of the boost inverter-based EV charger with second-order harmonic and switching frequency ripple current reduction, the dynamic behavior of the system, the transition between different operating modes, the DC-side capacitor voltage control above a minimum allowed voltage, and the DC-side capacitor sizing are extensively analyzed. The performance of the proposed system is verified using an experimental prototype, and presented results demonstrate the ability of the system to provide V2G reactive power compensation both with and without the EV battery. [ABSTRACT FROM PUBLISHER]

Published

2018

217. Comparative Analysis of Multilevel-High-Frequency-Link and Multilevel-DC-Link DC?DC Transformers Based on MMC and Dual-Active Bridge for MVDC Application.

Author

Zhao, Biao, Song, Qiang, Li, Jianguo, Xu, Xiaopeng, and Liu, Wenhua

Subjects

*DC transformers, *DC-to-DC converters, *BRIDGE circuits, *VOLTAGE control, *ELECTRIC network topology

Abstract

This paper gives a comprehensive comparison of multilevel high-frequency-link (HFL) dc transformer (abbreviated MDCT) based on modular multilevel converter (MMC) and multilevel-dc-link dc transformer (abbreviated ADCT) based on dual-active-bridge (DAB) for medium-voltage dc (MVDC) application. The topology, operation, HFL voltage and current, active and circulating power, characteristic currents, switching behaviors, and power loss are analyzed in detail. Both MDCT and ADCT have fault treatment ability for MVDC application. However, the installation and commissioning of ADCT are more flexible and simpler. In addition, the MDCT needs more switches and high-frequency (HF) inductors than ADCT in the MVDC side with the same voltage level, but the number of HF transformer can be reduced. Compared with MDCT, the ADCT has higher power transfer ability and lower circulating power, lower HFL voltage, and RMS current and peak values with the same transmission power in the MVDC side. However, the arm RMS and average currents of MDCT are lower than those of ADCT in the MVDC side. The switching performance of MDCT deteriorates when the MVDC voltage fluctuates, but the switching behaviors of half bridges are added to ADCT. The loss of ADCT almost keep the same when the MVDC voltage fluctuates, but the loss of MDCT changes a lot. Finally, a small-scale prototype platform with 1 kW/450 V/150 V is built and experimental results verify the correctness and effectiveness of the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2018

218. Analysis of Main Topologies of Shunt Active Power Filters Applied to Four-Wire Systems.

Author

Fabricio, Edgard Luiz Lopes, Junior, Samuel Carvalho Silva, Jacobina, Cursino Brandao, and de Rossiter Correa, Mauricio Beltrao

Subjects

*ELECTRIC power filters, *ELECTRIC network topology, *ELECTRIC power distribution grids, *HARMONIC distortion (Physics), *VOLTAGE control

Abstract

This paper presents a complete comparative study about the five most common configurations of shunt active power filter applied to four-wire distribution systems. In order to evaluate the applicability of the studied topologies, two scenarios of four-wire loads are investigated differing by level of zero-sequence harmonic contents. The analysis of simulation steady-state results comprise dc-link capacitor voltage and current stresses, harmonic distortion in grid currents, and semiconductor losses. The results show that structures with fourth inductor generate higher number of levels at output converter voltage. However, when they operate by compensating high levels of zero-sequence harmonics, they can present higher dc-link voltage and lower efficiency. Furthermore, system models, control strategy, and experimental results are presented as well. [ABSTRACT FROM PUBLISHER]

Published

2018

219. A Simplified Space Vector Modulation for Four-Level Nested Neutral-Point Clamped Inverters With Complete Control of Flying-Capacitor Voltages.

Author

Tan, Longcheng, Wu, Bin, Sood, Vijay, Xu, Dewei, Narimani, Mehdi, Cheng, Zhongyuan, and Zargari, Navid Reza

Subjects

*ELECTRIC inverters, *VOLTAGE control, *PULSE width modulation, *CAPACITORS, *COMPUTATIONAL complexity, *REDUNDANCY in engineering

Abstract

Four-level nested neutral-point clamped (NNPC) inverters experience severe voltage balancing problems under low output-frequency conditions when the conventional four-level space vector modulation (4L-SVM) technique is applied, which limits their wider application. In order to get a complete control of the flying-capacitor voltages, and to alleviate the calculation burden of conventional 4L-SVM, a simplified but effective 4L-SVM technique along with the voltage balance control (VBC) function is proposed in this paper. For low modulation indexes, zero and small vectors are selectively utilized and distributed to force the average charging and discharging time of flying capacitors to be equal to each other during every switching period, so that voltage ripples are greatly reduced to be within an acceptable level under low output-frequency conditions. For high modulation indexes, the simplification of conventional 4L-SVM for NNPC inverters into two-level SVM is proposed to reduce the computation complexity. Principles of the proposed 4L-SVM and VBC are elaborated in detail. The steady-state, transient-state, and VBC performances are investigated and compared with the case where the conventional 4L-SVM is applied. Simulation results of a 5 MVA inverter system and experimental results of a scaled-down 5 kVA inverter system are presented to validate the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2018

220. Virtual-Space-Vector PWM for a Three-Level Neutral-Point-Clamped Inverter With Unbalanced DC-Links.

Author

Wu, Xiang, Tan, Guojun, Ye, Zongbin, Yao, Guangyao, Liu, Zhan, and Liu, Guanghui

Subjects

*ELECTRIC inverters, *DIRECT current electric motors, *PULSE width modulation, *VOLTAGE control, *REACTIVE power

Abstract

In this paper, the properties and operation of the virtual-space-vector pulse-width modulation (PWM) for a three-level neutral-point-clamped inverter with unbalanced dc-links are studied. By quantitatively analyzing the characteristics of the revised space-vector diagram (SVD) with unbalanced dc-links, the defined virtual SVD (VSVD) for the unbalanced case is theoretically proven identical to the VSVD of the conventional virtual-space-vector PWM (VSVPWM) strategy with balanced dc-links. The well-developed and fast-processing methods to calculate the durations of the nearest three virtual vectors for the conventional VSVPWM can be directly utilized. In addition, a control strategy to realize the asymmetric control of the dc-link voltages with VSVPWM is also studied, and this method can adjust the unbalancing degree with a high accuracy for any modulation indexes and load power factors. Simulated and experimental results are given to validate the effectiveness. [ABSTRACT FROM PUBLISHER]

Published

2018

221. Single-Inductor Multioutput-Level Buck Converter for Reducing Voltage-Transition Time and Energy Overheads in Low Power DVS-Enabled Systems.

Author

Kapat, Santanu and Kumar, V. Inder

Subjects

*DC-to-DC converters, *VOLTAGE control, *POWER aware computing, *CMOS integrated circuits, *TRANSIENT analysis, *ELECTRIC network topology

Abstract

Dynamic voltage scaling (DVS) is a useful technique to optimize performance and efficiency of CMOS digital processors using dc–dc converters that require to meet extremely fast slew rate demand. However, there exist conflicting design criteria in existing DVS power supply architectures. This paper proposes a single-inductor multioutput-level buck converter for low power DVS-enabled systems. Under the time optimal voltage transition recovery, the proposed architecture: first, achieves the performance much beyond system's physical limits compared to conventional synchronous and multiphase buck converter based architectures; and second, can overcome conflicting power circuit design criteria in existing architectures. Also, a high-resolution quantized voltage can be realized by using a voltage-dithering technique. An analytical framework is considered to formulate various processor and converter-induced energy overheads. A comparative study is shown to evaluate the usefulness of the proposed architecture over the existing approaches under frequent voltage transitions. A prototype single-inductor four-output-level buck converter is tested and the performance improvements are demonstrated using test results. [ABSTRACT FROM PUBLISHER]

Published

2018

222. An Analytical Method to Evaluate and Design Hybrid Switched-Capacitor and Multilevel Converters.

Author

Lei, Yutian, Liu, Wen-Chuen, and Pilawa-Podgurski, Robert Carl Nikolai

Subjects

*SWITCHED capacitor circuits, *DC-to-DC converters, *ELECTRIC power conversion, *ENERGY dissipation, *VOLTAGE control, DESIGN & construction

Abstract

This paper investigates the use of multilevel conversion in dc–dc applications that require a large voltage conversion ratio. A quantitative method that can serve as a guide to compare and design multilevel topologies for large conversion ratio applications is presented. The proposed method keeps the conduction loss and switching loss constant across the different converters and employs the passive component volume as the single performance metric. As examples, flying capacitor multilevel converters and hybrid switched-capacitor (SC) converters are compared to conventional two-level buck converters, and are shown analytically to have significantly reduced passive component size. Three converter prototypes are implemented, based on the presented methodology to experimentally validate the method as well as demonstrate the advantages of multilevel and hybrid SC converters. [ABSTRACT FROM PUBLISHER]

Published

2018

223. High Power Density Design for a Modular Multilevel Converter With an H-Bridge Cell Based on a Volume Evaluation of Each Component.

Author

Nakanishi, Toshiki and Itoh, Jun-Ichi

Subjects

*ELECTRIC current converter design & construction, *BRIDGE circuits, *ELECTRIC loss in electric power systems, *HEAT sinks, *FLOW charts, *ELECTROLYTIC capacitors

Abstract

This paper presents a high power density design for a step-down rectifier incorporating a modular multilevel converter (MMC) in a power system connected to a 6.6 kV ac grid. In particular, the relationship among the number of cells, the output voltage of the MMC, and the overall volume is clarified. A proposed design flowchart focuses on minimizing volumes of cell capacitors, heat sinks, and arm inductors by using optimal number of cells. Moreover, the commercial electrolytic capacitors are used as the cell capacitor. Besides, the formulae used to determine the ripple currents in the electrolytic capacitor and the arm inductor are presented, along with that for the semiconductor loss. Each of these formulae were verified experimentally using a miniature model and theoretical values from all formulae agree with the measured values within minimal deviations that are discussed with regard to the design of a practical converter for a 6.6 kV system. Finally, the conditions necessary to achieve high power density in an MMC are provided, based on volume evaluations of the electrolytic capacitor, the arm inductor, and the heat sink. Using this optimization process, an MMC design achieved a volume reduction of approximately 90% compared to a conventional system. [ABSTRACT FROM PUBLISHER]

Published

2018

224. One-Cycle Control for Electrolytic Capacitor-Less Second Harmonic Current Compensator.

Author

Zhang, Li, Ruan, Xinbo, and Ren, Xiaoyong

Subjects

*ELECTROLYTIC capacitors, *SYNCHRONOUS capacitors, *ELECTRICAL harmonics, *POWER factor measurement, *VOLTAGE control

Abstract

The input power of the single-phase power factor correction ac–dc converter pulsates at twice the line frequency, while the output power of the single-phase dc–ac inverter pulsates at twice the output frequency. The pulsating power will result in second harmonic current (SHC) in the ac–dc converter and dc–ac inverter. In this paper, electrolytic capacitor-less second harmonic current compensator (SHCC) is presented to compensate the SHC. The SHCC has two operating modes, namely, charging mode and discharging mode. To achieve an excellent SHC compensation performance, a hybrid one-cycle control (OCC) is proposed to regulate the port current of the SHCC, and the SHCC can stably operate in both the charging mode and discharging mode. To avoid the mode detection required in the hybrid OCC and ensure seamless transition between the two modes, the OCC with dc bias is further proposed. Besides, a peak voltage control is proposed to regulate the storage capacitor voltage in the SHCC for reducing the power losses of the SHCC at light load. A 1-kW two-stage inverter with the SHCC is fabricated and tested, and the experimental results are provided to verify the effectiveness of the proposed control schemes. [ABSTRACT FROM AUTHOR]

Published

2018

225. A Branch Current Reallocation Based Energy Balancing Strategy for the Modular Multilevel Matrix Converter Operating Around Equal Frequency.

Author

Fan, Boran, Wang, Kui, Wheeler, Pat, Gu, Chunyang, and Li, Yongdong

Subjects

*MATRIX converters, *MODULAR construction, *FAULT tolerance (Engineering), *POWER capacitors, *VOLTAGE control, *FLUCTUATIONS (Physics)

Abstract

The modular multilevel matrix converter (M3C) is a promising topology for medium-voltage, high-power applications. Due to the modular structure, it is scalable and capable to produce high quality output waveforms and can be fault tolerant. However, the M3C suffers from low frequency capacitor voltage fluctuation if the output frequency is close to the input voltage frequency, which limits its application in adjustable speed drive fields. This paper presents a theoretical analysis in the phasor domain to find the branch-energy equilibrium point of the M3C when operating with equal input and output frequency first. Then, a branch energy balancing control method based on branch current reallocation is proposed to equalize the energy stored in the nine converter branches. With the proposed method, the M3C can effectively suppress the capacitor voltage fluctuation without injecting common-mode voltage or applying reactive power to the input side. Experimental results are presented to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

226. A Novel Method Based on Self-Power Supply Control for Balancing Capacitor Static Voltage in MMC.

Author

Luo, Longfei, Zhang, Yanbin, Jia, Lixin, and Yang, Ningning

Subjects

*ELECTRIC power, *VOLTAGE control, *CAPACITORS, *ELECTRIC current converters, *ELECTRIC power transmission, *RELIABILITY in engineering

Abstract

The modular multilevel converter is one of the most attractive converter topologies for high-voltage dc transmission systems, but it needs at least 10 min during the system uncontrolled precharge stage to verify the stability and reliability of submodules (SMs), making the capacitor static voltage balancing a key issue. This paper proposes a novel method based on self-power supply control for balancing capacitor static voltage. Because of the influence of self-power supplies on capacitor voltages, the method can keep the capacitor static voltage balanced by controlling the input characteristic of SMs self-power supplies. The control signals of self-power supplies have a fixed frequency and duty ratio, and they can be determined based on capacitor voltage sorting results and self-power supply output support capacitor. Compared with previous works, this method has less computation, and it does not rely on IGBTs and additional complex circuits except for the self-power supplies. This can save on the software and hardware costs. The proposed method also leads to improved equalizing resistances and reduced active power losses of the SMs. Simulations and experimental studies were conducted, and the results confirm the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

227. Hybrid-Bridge-Based DAB Converter With Voltage Match Control for Wide Voltage Conversion Gain Application.

Author

Xu, Guo, Sha, Deshang, Xu, Yaxiong, and Liao, Xiaozhong

Subjects

*ELECTRIC current converters, *VOLTAGE control, *VOLTAGE-frequency converters, *BRIDGE circuits, *PULSE width modulation, *ZERO voltage switching

Abstract

This paper proposes a voltage match (VM) control for hybrid-bridge-based dual active bridge (DAB) converter in wide voltage conversion gain applications. With the addition of an auxiliary half-bridge circuit, the topology becomes an integration of a half-bridge and a full-bridge DAB converter. Unlike other pulse width modulation generation method for DAB converters, this converter utilizes four-level voltage at one port of the transformer to obtain matched voltage waveforms within the range of twice the minimum conversion gain. Wide conversion gain, decoupling of the two power control variables and wide zero-voltage switching (ZVS) ranges can be achieved with the proposed VM control. Full load ranges of ZVS for the six main power switches can be achieved and the two auxiliary switches can also operate in a wide ZVS range. In addition, the power control is done only using two control variables and its implementation is very simple, only needing a divider and a conventional voltage regulator. These characteristics and benefits of the proposed control are verified by experimental results from a 1-kw converter prototype. [ABSTRACT FROM AUTHOR]

Published

2018

228. Control of an LLC Resonant Converter Using Load Feedback Linearization.

Author

Fang, Zhijian, Wang, Junhua, Duan, Shanxu, Liu, Kaipei, and Cai, Tao

Subjects

*CONVERTERS (Electronics), *ELECTRONIC linearization, *APPROXIMATION theory, *ELECTRONIC modulation, *VOLTAGE control

Abstract

LLC resonant converter is a nonlinear system, limiting the use of typical linear control methods. This paper proposed a new nonlinear control strategy, using load feedback linearization for an LLC resonant converter. Compared with the conventional PI controllers, the proposed feedback linearized control strategy can achieve better performance with elimination of the nonlinear characteristics. The LLC resonant converter's dynamic model is built based on fundamental harmonic approximation using extended describing function. By assuming the dynamics of resonant network is much faster than the output voltage and controller, the LLC resonant converter's model is simplified from seven-order state equations to two-order ones. Then, the feedback linearized control strategy is presented. A double loop PI controller is designed to regulate the modulation voltage. The switching frequency can be calculated as a function of the load, input voltage, and modulation voltage. Finally, a 200 W laboratory prototype is built to verify the proposed control scheme. The settling time of the LLC resonant converter is reduced from 38.8 to 20.4 ms under the positive load step using the proposed controller. Experimental results prove the superiority of the proposed feedback linearized controller over the conventional PI controller. [ABSTRACT FROM PUBLISHER]

Published

2018

229. Inverter Power Control Based on DC-Link Voltage Regulation for IPMSM Drives Without Electrolytic Capacitors.

Author

Zhao, Nannan, Wang, Gaolin, Xu, Dianguo, Zhu, Lianghong, Zhang, Guozhu, and Huo, Junya

Subjects

*ELECTRIC inverters, *VOLTAGE regulators, *PERMANENT magnet motors, *SYNCHRONOUS electric motors, *ELECTROLYTIC capacitors

Abstract

DC-link electrolytic capacitor critically affects the lifetime of the motor drive system. This paper proposes an inverter power control strategy based on dc-link voltage regulation for the electrolytic capacitor-less interior permanent magnet synchronous motor drive system. The dc-link electrolytic capacitor is replaced by a small film capacitor and the power factor correction circuit is also eliminated. Hence, the inverter power should be regulated effectively to achieve high input power factor and low grid current harmonics. The inverter power control loop based on proportional resonant (PR) controller is established to regulate the inverter power into sinusoidal wave. The PR controller can be designed to achieve a high gain at the desired frequency and the parameters are easy to design due to the simple structure. In addition, a power compensation method based on the dc-link voltage regulation is used to diminish the error of inverter power control, which does not depend on the precise calculation and is easy to realize. The effectiveness of the proposed method is demonstrated by the experimental results on an air conditioner. The input power factor can reach 0.992 and the harmonics of grid current are considerably lower than the requirement of EN61000-3-2 standard. [ABSTRACT FROM PUBLISHER]

Published

2018

230. A Self-Balanced Step-Up Multilevel Inverter Based on Switched-Capacitor Structure.

Author

Taghvaie, Amir, Adabi, Jafar, and Rezanejad, Mohammad

Subjects

*ELECTRIC inverters, *SWITCHED capacitor circuits, *BIPOLAR integrated circuits, *VOLTAGE control, *HARMONIC distortion (Physics)

Abstract

In this paper, a dc to ac converter with the ability of voltage increasing is presented. This inverter is designed in a way that just one dc source is used. Also, by using power storage technique and with combining charged capacitors and dc source in series form, output voltage levels can be increased. This inverter is in a modular structure and has the ability of capacitor's voltage self-balancing. H-bridge inverter was not used at the end of the proposed converter and all elements tolerate a voltage stress equal to the amount of input dc source. This leads to remarkable decrease of total standing voltage and peak inverse voltage. Other advantage of the proposed inverter is its potentiality of performance in high-frequency applications. The modular form of the proposed inverter provides the potentiality of extension to higher voltage levels and eases the maintenance. Moreover, considering to the fact that the stress of all components of the suggested inverter is equal to the input source, the performance in high voltage is added to the characteristics of the proposed inverter. The nine-level structure of the proposed inverter is simulated and laboratory test is carried out for the verification of its performance. [ABSTRACT FROM PUBLISHER]

Published

2018

231. A Family of Resonant Two-Switch Boosting Switched-Capacitor Converter With ZVS Operation and a Wide Line Regulation Range.

Author

Li, Shouxiang, Zheng, Yifei, Wu, Bin, and Smedley, Keyue Ma

Subjects

*RESONANT inverters, *SWITCHED capacitor circuits, *ZERO voltage switching, *ZERO current switching, *DIODES

Abstract

In this paper, a family of resonant two-switch boosting switched-capacitor converters (RTBSCs) with ZVS operation and a wide line regulation range is proposed. Based on our previously proposed two-switch boosting switched-capacitor converters (TBSCs), only a small resonant inductor is added, while two bulky capacitor banks are replaced by two much smaller resonant capacitors. Furthermore, by operating RTBSC above the resonant frequency, the transistors are ZVS turned on and diodes are Zero-current-switching (ZCS) turned on/off. This eliminates the hard-switched phenomenon of TBSC, leading to reduced component size by increasing the operating frequency without sacrificing the overall efficiency. In addition, the voltage-gain range of the RTBSCs is largely expanded and hence the input-voltage range is increased remarkably for regulated output voltage applications. Meantime, the voltage stress on transistors and diodes remains low, equal to the input voltage. A 3X RTBSC prototype with maximum output voltage 150 V, maximum output power 140 W, and a peak efficiency of 98.3% was built. The analysis is verified by simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

232. Fully Integrated Digitally Assisted Low-Dropout Regulator for a NAND Flash Memory System.

Author

Yoon, Kye-Seok, Kim, Hyun-Sik, Qu, Wanyuan, Yuk, Young-Sub, and Cho, Gyu-Hyeong

Subjects

*FLASH memory, *COMPLEMENTARY metal oxide semiconductors, *TRANSISTORS, *GOVERNORS (Machinery), *ELECTRIC potential

Abstract

In this paper, a fully integrated digitally assisted low-dropout regulator (LDO) for a NAND flash memory system is proposed and verified using 500 nm I/O CMOS transistors. By combining an amplifier (AMP)-based LDO with a comparator (CMP)-based LDO, the proposed LDO achieves both fast load response in the transient state and accurate regulation in the steady state, which are advantages of the CMP-based LDO and AMP-based LDO, respectively. Moreover, loop frequency stability is satisfied in a wide range of load currents between 0 and 150 mA by using the simple structure of the gm-boost cell to insert an auxiliary path. For an input voltage range of 2.3–3 V and an output voltage of 2.1 V, the measured output droop is 225 mV for a 150 mA load step in the load transition time of 20 ns with the total bias current of 81\,\mu \rmA. The fabricated prototype chip occupies 160\,\times \,610\,\mu \rmm^2 with an on-chip output capacitor of 2 nF. [ABSTRACT FROM AUTHOR]

Published

2018

233. An Active-Rectifier-Based Maximum Efficiency Tracking Method Using an Additional Measurement Coil for Wireless Power Transfer.

Author

Mai, Ruikun, Liu, Yeran, Li, Yong, Yue, Pengfei, Cao, Guangzhong, and He, Zhengyou

Subjects

*ELECTRIC current rectifiers, *WIRELESS power transmission, *COILS (Magnetism), *ENERGY transfer, *ENERGY consumption, *VOLTAGE control

Abstract

The efficiency of wireless power transfer (WPT) systems is highly dependent on the load, which may change in a wide range in field applications. Besides, the detuning of WPT systems caused by the component tolerance and aging of inductors and capacitors can also decrease the system efficiency. In order to track the maximum system efficiency under varied loads and detuning conditions in real time, an active single-phase rectifier (ASPR) with an auxiliary measurement coil (AMC) and its corresponding control method are proposed in this paper. Both the equivalent load impedance and the output voltage can be regulated by the ASPR and the inverter, separately. First, the fundamental harmonic analysis model is established to analyze the influence of the load and the detuning on the system efficiency. Second, the soft-switching conditions and the equivalent input impedance of ASPR with different phase shifts and pulse widths are investigated in detail. Then, the analysis of the AMC and the maximum efficiency control strategy are provided in detail. Finally, an 800-W prototype is set up to validate the performance of the proposed method. The experimental results show that with 10% tolerance of the resonant capacitor in the receiver side, the system efficiency with the proposed approach reaches 91.7% at rated 800-W load and 91.1% at 300-W light load, which has an improvement by 2% and 10% separately compared with the traditional diode rectifier. [ABSTRACT FROM PUBLISHER]

Published

2018

234. Feedback Linearization-Based Current Control Strategy for Modular Multilevel Converters.

Author

Yang, Shunfeng, Wang, Peng, and Tang, Yi

Subjects

*ELECTRONIC feedback, *ELECTRONIC linearization, *ELECTRIC controllers, *NONLINEAR systems, *NONLINEAR functional analysis

Abstract

Modular multilevel converters (MMCs) are multi-input multi-output (MIMO) nonlinear systems. The control systems for MMCs are required to simultaneously achieve multiple control objectives, e.g., output current regulation, submodule capacitor voltage control, and circulating ripple currents suppression. Existing cascaded control strategies for MMCs achieve those control objectives with relatively complex controllers, and the controller parameter design is normally difficult for such nonlinear systems with highly coupled states. In view of this, a feedback linearization-based current control strategy is proposed for an MMC system in this paper. The nonlinear state function model of the MMC is presented and transformed to a linearized and decoupled form with the help of the input–output feedback linearization technique. Based on the linearized system, simple linear controllers are employed to regulate the output and inner differential currents of the MMC, which significantly reduces the difficulty in controller design. The stability of the proposed control strategy is analyzed. The experimental verification results show that, compared to the conventional cascaded control strategies for MMCs, the proposed feedback linearization control strategy is able to achieve improved steady-state and dynamic performances. The robustness of the proposed control strategy against parametric uncertainties is experimentally investigated. [ABSTRACT FROM PUBLISHER]

Published

2018

235. A General Approach to Programmable and Reconfigurable Emulation of Power Impedances.

Author

Li, Sinan, Qi, Wenlong, Tan, Siew-Chong, Hui, S. Y., and Tse, Chi K.

Subjects

*PROGRAMMABLE controllers, *ADAPTIVE computing systems, *EMULATION software, *ELECTRIC impedance, *STATIC VAR compensators

Abstract

Starting with a brief review on the existing methods of impedance emulation, this paper addresses a general and systematic approach to programmable and reconfigurable emulation of power impedances. The proposed approach not only enables the impedance value to be programed, but also allows the characteristics (i.e., type) of the impedance to be reconfigured instantly during the operation. Based on the proposed control method, emulation of at least six types of emulated power impedances (EPI) can be easily attained. In particular, it is theoretically and practically demonstrated that the impedance characteristic can be emulated through a combination of different functions. The systematic derivation of these functions is explained. New techniques that compensate the circuit power losses are introduced. This general approach has been practically verified in several EPI. Both steady-state and dynamic performance of these EPI confirm the programmability and reconfigurability. It is envisaged that the proposed method can be applied to a range of functions, such as power filtering, energy storage, and even power conversion based on direct impedance control. [ABSTRACT FROM PUBLISHER]

Published

2018

236. Active Power Decoupling for Submodules of a Modular Multilevel Converter.

Author

Kong, Zenghui, Huang, Xin, Wang, Ze, Xiong, Jian, and Zhang, Kai

Subjects

*MATHEMATICAL decoupling, *SUBMODULAR functions, *CASCADE converters, *ELECTRIC power filters, *CAPACITORS, *POWER density

Abstract

The modular multilevel converter (MMC) is receiving wide acceptance in both high- and medium-voltage (MV) applications. However, due to the low (fundamental and second-order) frequency ripple powers in the submodule (SM) capacitors, large capacitance is required to smooth the SM voltage. The SM capacitors account for a large portion of volume and weight in the MMC system. Present methods (e.g., circulating current control, power channels linking upper and lower arms) cannot eliminate the fundamental and second-order ripple powers simultaneously. This paper investigates the feasibility of an active power decoupling technique for solving this issue. By adding a buck-type active power filter (APF) circuit (which contains another energy-storage capacitor), the low-frequency ripple powers can be transferred to the APF capacitor. This significantly reduces the SM voltage ripple and therefore the total capacitance of the SM. To enhance voltage ripple suppression, APF capacitor voltage reference is modified in a closed-loop manner, and a proportional-integral plus repetitive controller is proposed. Simulations and experimental results prove the validity of the method. A comparison with the traditional MMC shows that it can significantly reduce system volume and improve power density. The method is best suited for MV applications where power density is given a high priority. [ABSTRACT FROM PUBLISHER]

Published

2018

237. Zero-Voltage Switching PWM Strategy Based Capacitor Current-Balancing Control for Half-Bridge Three-Level DC/DC Converter.

Author

Liu, Dong, Deng, Fujin, Zhang, Qi, and Chen, Zhe

Subjects

*CAPACITORS, *ZERO voltage switching, *PULSE modulation, *DC-to-DC converters, *THERMAL stresses

Abstract

The current imbalance among the two input capacitors is one of the important issues of the half-bridge three-level (HBTL) dc/dc converter, which would affect system performance and reliability. In this paper, a zero-voltage switching (ZVS) pulse-wide modulation (PWM) strategy including two operation modes is proposed. Based on the proposed ZVS PWM strategy, a capacitor current-balancing control is proposed for the HBTL dc/dc converter, where the currents on the two input capacitors can be kept balanced by alternating the two operation modes of the proposed ZVS PWM strategy. Therefore, the proposed control strategy can improve the performance and reliability of the converter in the aspect of balancing the thermal stresses and lifetimes among the two input capacitors. Finally, simulation and experimental studies are conducted and results verify the proposed control strategy. [ABSTRACT FROM PUBLISHER]

Published

2018

238. An Improved PWM Strategy for Z-Source Inverter With Maximum Boost Capability and Minimum Switching Frequency.

Author

Zhang, Yan, Liu, Jinjun, Li, Xinying, Ma, Xiaolong, Zhou, Sizhan, Wang, Hongliang, and Liu, Yan-Fei

Subjects

*ELECTRIC inverters, *ANALOG-to-digital converters, *ZERO voltage switching, *PULSE width modulation, *CAPACITORS, *CLOSED loop systems

Abstract

Z-source inverter provides a competitive single-stage dc–ac power conversion with the capability of both buck and boost voltage regulation. In order to maximize voltage gain and to increase efficiency, this paper proposes an improved pulse-width modulation (PWM) strategy. By adjusting the shoot-through duty ratio of one-phase leg, it regulates the average value of intermediate dc-link voltage, which is the same as the instantaneous maximum of three-phase line voltage in one switching time period (Ts) . And the other two-phase legs maintain the fixed switching states. Thus, the equivalent switching frequency of power devices in the inverter bridge is reduced to 1/ 3fs (fs is the frequency corresponding to Ts). The operating principles and closed-loop controller design are analyzed and verified by simulation and experiments. Compared with the existing PWM strategies, the improved PWM (IPWM) strategy demonstrates higher efficiency under full operation range of low voltage gain (1.27-2) application. However, with the IPWM strategy, the inductor current and capacitor voltage contain six-time-line-frequency ripples, which consequently require large size of the passive components when the output frequency is very low. Thus, it is also suitable for 400–800-Hz medium frequency aircraft and vessel power supply system due to a relatively high output line frequency. Furthermore, the idea of IPWM strategy can be extended to other kinds of three-phase impedance network-based inverters. [ABSTRACT FROM PUBLISHER]

Published

2018

239. Power Control With Z-Source Converter Based Unified Power Flow Controller.

Author

Thirumalaivasan, R., Xu, Yunjian, and Janaki, M.

Subjects

*ELECTRIC controllers, *REACTIVE power, *ROTARY converters, *ELECTRIC potential measurement, *COMPUTER simulation

Abstract

In this paper, we propose a Z-source converter (ZSC)-based unified power flow controller (ZSC-UPFC) to enhance power control for long transmission lines. As a multifunctional controller, the UPFC has been adopted to regulate both the active and reactive power flows in transmission lines and to control the AC bus voltage. A recently proposed converter topology, ZSC, uses a Z-network on its DC side to support the desired AC output voltage. The proposed ZSC-UPFC configuration places a Z-network between the dc-link capacitor and the series converter to boost the series converter DC voltage. The integration of Z-network provides the desired converter voltage even with reduced dc-link capacitor voltage setting. We develop a detailed three-phase model for the proposed ZSC-UPFC by modeling the converter operation with switching functions, which are generated by the space vector pulse width modulation (SVPWM) technique. We conduct linear analysis on the D-Q model as well as extensive transient simulation (based on a detailed nonlinear three-phase model) to evaluate the performance of the overall system with the proposed ZSC-UPFC configuration. Our simulation results demonstrate the effectiveness of ZSC-UPFC: 1) The series converter provides the series compensation in a long transmission line with Z-network, and 2) the shunt converter maintains a constant dc-link capacitor voltage and provides reactive power support for the AC bus. [ABSTRACT FROM PUBLISHER]

Published

2017

240. A Transition Arm Modular Multilevel Universal Pulse-Waveform Generator for Electroporation Applications.

Author

Elgenedy, Mohamed A., Darwish, Ahmed, Ahmed, Shehab, and Williams, Barry W.

Subjects

*ELECTRIC generators, *ELECTROPORATION, *ELECTRIC fields, *ELECTRIC controllers, *ELECTRIC current converters

Abstract

High-voltage (HV) pulses are used in electroporation to subject pulsed electric field (PEF) onto a sample under treatment. Pulse-waveform shape, voltage magnitude, pulse duration, and pulse repetition rate are the basic controllable variables required for particular PEF application. In practice, a custom-made pulse generator is dedicated for each PEF application with limited flexibility in changing these variables. In this paper, a universal pulse-waveform generator (UPG) is proposed, where the controller software algorithm can manipulate a basic generated multilevel pulse waveform to emulate many different PEF pulse waveforms. The commonly used PEF HV pulse waveforms can be generated as bipolar or monopolar with controllable pulse durations, repetition times, and voltage magnitudes. The UPG has the ability to generate multilevel pulses that have controllable $dv/dt$, which allows reduction of the electromagnetic interference generated by the converter. The UPG topology is based on half-bridge modular multilevel converter (HB-MMC) cells forming two transition arms in conjunction with two bistate arms, together creating an H-bridge. The HB-MMC cell capacitors provide a controllable energy source which charge from the dc input supply and discharge across the load, while the two bistate arms allow charging the HB-MMC cell capacitors. Hence, the UPG topology offers modularity, redundancy, and scalability. The HB-MMC individual cell capacitance is low and the cell voltages are balanced by employing the sorting and rotating algorithm used in conventional HB-MMC topologies for HV dc transmission applications. The viability of the proposed UPG converter is validated by MATLAB/Simulink simulation and scaled-down experimentation. [ABSTRACT FROM PUBLISHER]

Published

2017

241. Control of Modular Multilevel Converter With Parallel Connectivity?Application to Battery Systems.

Author

Goetz, Stefan M., Li, Zhongxi, Liang, Xinyu, Zhang, Chengduo, Lukic, Srdjan M., and Peterchev, Angel V.

Subjects

*CASCADE converters, *ELECTRIC batteries, *ELECTRICAL load, *SWITCHING circuits, *FEASIBILITY studies

Abstract

This paper presents a multiobjective real-time controller for a modular multilevel converter capable of parallel module connectivity, the so-called modular multilevel series parallel converter (MMSPC). The MMSPC topology allows the batteries to be dynamically rewired in various series–parallel configurations, generating a wide range of output voltage levels. The novel control method parallelizes the modules to balance their voltages without the need for individual module voltage monitoring. Additionally, the controller optimizes across the large number of feasible system configurations to minimize switching and conduction losses. Finally, the controller efficiently encodes the system configuration with module interconnection states rather than the module switch states, which substantially simplifies control. Furthermore, this work experimentally validates the MMSPC topology and concept. In the prototype, the parallel mode reduced the system losses at 5 kW output power by 18% and 24% for load power factors of 1.0 and 0.8, respectively. Sensorless balancing via parallelization maintained well-matched module voltages (standard deviation = 0.045 V) over a 5-h battery discharge with highly variable load current. The reduced conduction losses and simple balancing capability of the MMSPC can enable new applications at medium and low voltages that benefit from its high-quality output, elimination of filtering magnetics, fast response, and modularity. [ABSTRACT FROM AUTHOR]

Published

2017

242. Dynamic Voltage Restorer Using Switching Cell Structured Multilevel AC–AC Converter.

Author

Kim, Sanghun, Kim, Heung-Geun, and Cha, Honnyong

Subjects

*ELECTRIC potential, *SWITCHING circuits, *AC-AC transformers, *CASCADE converters, *PULSE width modulation

Abstract

Dynamic voltage restorer (DVR) technology has become a mature power quality product. In high-power applications, DVR using a multilevel converter is commonly used. However, DVR using a multilevel direct pulse width modulation (PWM) ac–ac converter has not been well studied. This paper presents a new DVR topology using a cascaded multilevel direct PWM ac–ac converter. In the proposed scheme, the unit cell of the multilevel converter consists of a single-phase PWM ac-ac converter using switching cell structure with coupled inductors. Therefore, the multilevel converter can be short- and open-circuited without damaging the switching devices. Neither lossy RC snubber nor a dedicated soft commutation strategy is required in the proposed DVR. This improves the reliability of the DVR system. The output voltage levels of the multilevel converter increase with the number of cascaded unit cells, and a high ac output voltage is obtained by using low-voltage-rating switching devices. Furthermore, a phase-shifted PWM technique is applied to significantly reduce the size of the output filter inductor. A 1-kW prototype of single-phase DVR is developed, and its performance is experimentally verified. Finally, the simulation results are shown for a three-phase DVR system. [ABSTRACT FROM AUTHOR]

Published

2017

243. A Frequency Adaptive Phase Shift Modulation Control Based LLC Series Resonant Converter for Wide Input Voltage Applications.

Author

Shakib, S. M. Showybul Islam and Mekhilef, Saad

Subjects

*PHASE shifters, *ZERO voltage switching, *CASCADE converters, *ELECTRIC potential, *ELECTRIC network topology

Abstract

This paper presents an isolated LLC series resonant DC/DC converter with novel frequency adaptive phase shift modulation control, which suitable for wide input voltage (200–400 V) applications. The proposed topology integrates two half-bridge in series on the primary side to reduce the switching stress to half of the input voltage. Unlike the conventional converter, this control strategy increases the voltage gain range with zero-voltage-switching (ZVS) to all switches under all operating voltage and load variations. Adaptive frequency control is used to secure ZVS in the primary bridge with regards to load change. To do so, the voltage gain becomes independent of the loaded quality factor. In addition, the phase shift control is used to regulate the output voltage as constant under all possible inputs. The control of these two variables also significantly minimizes the circulating current, especially from the low-voltage side, which increases the efficiency as compared to a conventional converter. Experimental results of a 1-Kw prototype converter with 200–400-V input and 48-V output are presented to verify all theoretical analysis and characteristics. [ABSTRACT FROM AUTHOR]

Published

2017

244. A Transformerless Bipolar Modular Multilevel DC?DC Converter With Wide Voltage Ratios.

Author

Du, Sixing and Wu, Bin

Subjects

*ELECTRIC transformers, *ELECTRIC cells, *DC-to-DC converters, *FEASIBILITY studies, *ELECTRIC circuits

Abstract

This paper presents a transformerless bipolar dc–dc converter based on series-connected submodules. It is intended for transforming dc voltage and managing power flow for medium/high-voltage dc grids. The dc–dc converter is composed of positive-pole and negative-pole subsystems, each of which consists of six arms/branches. Every two arms and one branch are constructed into a T-type circuit with the outer terminals interface to primary- and secondary-side dc buses. The two T-type circuits in one subsystem are connected in parallel to transmit power between primary and secondary sides. The transformerless structure (none bulky coupled inductors as well) solves the challengeable insulation and cooling issues of the extremely high-power magnetics in prior arts, while not sacrificing the power efficiency and system reliability. A $ \pm $ 10-kV 2-MW simulation model performed in MATLAB/Simulink verifies the feasibility of the bipolar dc–dc converter. Experimental results obtained from a laboratory setup also confirm the validation of the proposal. [ABSTRACT FROM AUTHOR]

Published

2017

245. Fault-Tolerant Control of MMC With Hot Reserved Submodules Based on Carrier Phase Shift Modulation.

Author

Li, Kai, Yuan, Liqiang, Zhao, Zhengming, Lu, Sizhao, and Zhang, Yiming

Subjects

*POWER electronics, *PHASE shifters, *ELECTRONIC modulation, *VOLTAGE control, *MICROCONTROLLERS

Abstract

Reliability is one of the most important challenges for the modular multilevel converter (MMC), which is composed of a large number of power electronics submodules (SMs). In order to increase the system reliability, the reserved SMs are often utilized. A novel strategy is proposed in this paper to implement the fault-tolerant control of MMC with the hot reserved SMs based on the carrier phase shift modulation. All the SMs, including the hot reserved SMs, work in the operating mode and the standby mode in turns. A rotating sliding choice box is adopted to select the operating SMs and the corresponding phase-shift angles, which enables the equal burden of each SM. Once the faults are detected and localized, the reserved SMs can simultaneously replace the bypassed failed SMs, which guarantees the fault-tolerant operation with a nearly seamless transition and very short recovery time. Furthermore, the line cycle is set as the rotating period in the control strategy, without increasing much switching loss. The mismatch pulses are greatly reduced as well. This technique can also be easily implemented in a DSP or microcontroller. Simulations in MATLAB/Simulink and experiments based on a downscaled MMC prototype have verified the feasibility and effectiveness of the proposed control strategy. [ABSTRACT FROM PUBLISHER]

Published

2017

246. Steady-State Modeling of Modular Multilevel Converter Under Unbalanced Grid Conditions.

Author

Shi, Xiaojie, Wang, Zhiqiang, Liu, Bo, Li, Yalong, Tolbert, Leon M., and Wang, Fred

Subjects

*CONVERTERS (Electronics), *ELECTRIC potential, *ELECTRIC capacity, *ELECTRIC inverters, *FAULT tolerance (Engineering)

Abstract

This paper presents a steady-state model of MMC for the second-order phase voltage ripple prediction under unbalanced conditions, taking the impact of negative-sequence current control into account. From the steady-state model, a circular relationship is found among current and voltage quantities, which can be used to evaluate the magnitudes and initial phase angles of different circulating current components. Moreover, in order to calculate the circulating current in a point-to-point MMC-based HVdc system under unbalanced grid conditions, the derivation of equivalent dc impedance of an MMC is discussed as well. According to the dc impedance model, an MMC inverter can be represented as a series connected R–L–C branch, with its equivalent resistance and capacitance directly related to the circulating current control parameters. Experimental results from a scaled-down three-phase MMC system under an emulated single-line-to-ground fault are provided to support the theoretical analysis and derived model. This new models provides an insight into the impact of different control schemes on the fault characteristics and improves the understanding of the operation of MMC under unbalanced conditions. [ABSTRACT FROM PUBLISHER]

Published

2017

247. Improving the Light-Load Regulation Capability of LLC Series Resonant Converter Using Impedance Analysis.

Author

Yeon, Cheol-O, Kim, Jong-Woo, Park, Moo-Hyun, Lee, Il-Oun, and Moon, Gun-Woo

Subjects

*CONVERTERS (Electronics), *VOLTAGE control, *CAPACITORS, *TOPOLOGY, *ELECTRIC impedance, *ELECTRICAL load

Abstract

Generally, an LLC series resonant converter (LLC SRC) is an attractive topology for applications, which require wide input variation and high conversion efficiency because of its wide gain capability and soft-switching capability. However, there is a regulation problem in which the output voltage increases as the load current decreases. In this paper, Bode plot and impedance asymptote analysis were conducted to obtain an intuitive sense of the regulation characteristic of LLC SRC under the light-load condition. Moreover, to improve the regulation capability, a new resonant tank with an additional capacitor is proposed. Its design guidelines were determined by Bode plot and impedance asymptote analysis. Therefore, the proposed LLC SRC achieves very light load regulation, while it maintains the advantages of typical LLC SRCs. [ABSTRACT FROM PUBLISHER]

Published

2017

248. Robust Active Damping Methods for LCL Filter-Based Grid-Connected Converters.

Author

Ben Said-Romdhane, Marwa, Naouar, Mohamed Wissem, Slama-Belkhodja, Ilhem, and Monmasson, Eric

Subjects

*CONVERTERS (Electronics), *HARMONIC suppression filters, *ELECTRIC potential, *PID controllers, *ELECTRIC power distribution grids, *DIGITAL control systems, *ELECTRIC inductance

Abstract

Grid-connected converters (GcCs) employ LCL filters instead of simple L filters in order to meet new grid codes and their on-going changes in the near future. Active damping methods, without power losses, are preferred to passive ones for solving the resonance problems of LCL-filter-based GcCs ( LCL-GcCs). However, large changes in the grid inductance (typically under weak grid conditions and in rural areas) may compromise the system stability. Moreover, the delay of digital controllers will change system phase-frequency characteristics and consequently will affect the system stability. In view of this, this paper proposes a systematic design procedure for the active damping of voltage-oriented PI control for LCL- GcCs. The procedure considers active damping methods based on capacitor current feedback and is aimed to ensure stable operation under severe grid inductance variations while taking into account the influence of digital control delay and LCL filter parameters changes on the system stability. Simulation and experimental results are presented and discussed in order to validate the proposed design procedure. [ABSTRACT FROM PUBLISHER]

Published

2017

249. Active Virtual Ground—Bridgeless PFC Topology.

Author

Ho, Carl Ngai Man, Li, River Tin-ho, and Siu, Ken King-Man

Subjects

*ELECTRIC power factor, *REACTIVE power, *ELECTRIC potential, *ELECTRIC power conversion, *ELECTRIC inductance

Abstract

The paper presents a new bridgeless power factor correction (PFC) topology, using a recently proposed controllable LCL filter, namely active virtual ground to achieve efficient power conversion, and high-frequency common mode voltage (CM) reduction. The proposed PFC circuit consists of high-frequency semiconductors for shaping inductor current and low-frequency semiconductors to form two different LCL structures for different conditions. This reduces grid differential mode current ripple or inductance. Besides, the PFC CM voltage, a main problem of bridgeless PFCs, is significantly reduced, since the capacitor in the LCL filter clamps the voltage between the grid and the converter ground. The performance of the proposed PFC is experimentally verified. The results show that the proposed PFC guarantees sinusoidal input current, low high-frequency common-mode voltage noise, and has a good agreement with the theoretical findings. [ABSTRACT FROM AUTHOR]

Published

2017

250. Energy Balancing Improvement of Modular Multilevel Converters Under Unbalanced Grid Conditions.

Author

Leon, Andres E. and Amodeo, Santiago J.

Subjects

*ELECTRIC current converters, *ELECTRIC currents, *ELECTRIC power distribution grids, *ELECTRIC controllers, *ELECTRIC potential

Abstract

This paper presents a feedback/feed-forward control strategy to improve the voltage balancing of modular multilevel converters (MMCs) under unbalanced grid conditions. The inclusion of a feed-forward compensation improves the disturbance rejection capability against asymmetrical faults and sudden voltage imbalances in the ac grid. The floating capacitor voltages of the MMC are controlled in two stages. The first one equally distributes the voltages in each arm, and the second one balances the energy among the six arms. This last control stage is also divided into the called horizontal and vertical balancing. Based on a detailed analysis of the power terms disturbing the MMC arm energies, the control strategy is tailored to improve the voltage transient response by adding feed-forward terms to both horizontal and vertical balancing controls. In addition, various approaches to manage the MMC under unbalanced grid conditions are compared regarding several aspects, such as capacitor voltage ripple, balancing performance, and negative-sequence current injection. Advantages and disadvantages of both the proposed and the conventional energy-based control schemes are also studied, showing that the voltage control performance can be improved by enhancing the existing MMC control systems. [ABSTRACT FROM AUTHOR]

Published

2017