Showing total 470 results

1. A Current Limiting Strategy With Parallel Virtual Impedance for Three-Phase Three-Leg Inverter Under Asymmetrical Short-Circuit Fault to Improve the Controllable Capability of Fault Currents.

Author

Lin, Xinchun, Liang, Zhigang, Zheng, Yun, Lin, Yibin, and Kang, Yong

Subjects

*FAULT currents, *PULSE width modulation transformers, *SHORT-circuit currents, *IMPEDANCE control, *FILTER paper, *VOLTAGE control, *ELECTRIC potential

Abstract

Voltage-controlled three-phase three-leg inverters are widely applied in various occasions. The inverters are generally switched to the current-controlled mode to limit the fault currents when short-circuit faults happen. Under symmetrical fault, the inverter can be controlled as a symmetrical, three-phase current source. However, the voltage limiting will happen under asymmetrical fault. As a result, the fault phase currents will be distorted and cannot be completely controlled. Considering that the voltage limiting is mainly caused by large load impedance of healthy phase under asymmetrical fault, the voltage limiting is avoided by paralleling the virtual impedance with the output filter capacitor in this paper. As a result, the current limiting loop is not broken and the fault phase currents can be effectively controlled. The implementation of virtual impedance in control system and the influence of virtual impedance on the stability of system are also analyzed in detail in this paper. The theoretical results are validated by experiments. [ABSTRACT FROM AUTHOR]

Published

2019

2. A Switched Capacitive Filter-Based Harmonic Elimination Technique by Generating a 30-Sided Voltage Space Vector Structure for IM Drive.

Author

R, Rakesh, Ramachandran, Krishna Raj, Yadav, Apurv Kumar, Gopakumar, K., Umanand, Loganathan, and Matsuse, Kouki

Subjects

*VECTOR spaces, *SPACE frame structures, *INDUCTION machinery, *HARMONIC analysis (Mathematics), *ELECTRIC potential, *TORQUE

Abstract

This paper proposes a novel polygonal voltage space vector structure (SVS) having 30 sides, for a star-connected induction motor drive. The SVS eliminates the presence of harmonics up to 25th order from motor phase voltage throughout the entire modulation range, providing a torque profile devoid of lower order pulsations. Linear modulation is extended till 99.63% of base speed without exceeding the motor phase voltage rating. Topology consists of a dc-link fed primary inverter and two equal low voltage modular capacitor fed secondary inverters. Here the harmonics generated by the primary inverter is canceled by the secondary inverter which acts as a switched capacitive filter. Detailed description of the SVS generation and timing calculations are provided in this paper. Effectiveness of the proposed scheme is validated using experimental results, inverter loss calculations, and harmonic analysis. [ABSTRACT FROM AUTHOR]

Published

2020

3. An Enhanced Multiple Harmonics Analysis Method for Wireless Power Transfer Systems.

Author

Fang, Yaoran, Pong, Bryan Man Hay, and Hui, Ron Shu Yuen

Subjects

*WIRELESS power transmission, *GRAPHICAL user interfaces, *ELECTRIC potential, *ELECTRIC circuits, *PROCESS optimization, *HARMONIC analysis (Mathematics)

Abstract

First harmonic analysis (FHA) is arguably the most widely used analytical technique for wireless power transfer (WPT) circuits due to its simplicity. Although FHA can provide closed-form solutions, the existence of rectifier diode forward voltage drop and higher order harmonics, especially the second and third harmonics at variable duty cycle operation, can significantly deteriorate its accuracy. This paper presents an accurate and efficient method called enhanced multiple harmonic analysis (eMHA) for the optimal design and optimal control of WPT systems. The eMHA method considers the nature of nonlinear rectification networks under nonsinusoidal current and reexamines the concept of the equivalent load. As a result, the rectified WPT system is transformed into a series of linear systems with complex load impedances. The steady-state electric quantities can be then explicitly calculated. This enables eMHA to seamlessly work with numerical optimization algorithms to facilitate the automated design and optimization of WPT systems. An example of optimal design and optimal control of a 10 W WPT system is demonstrated. The results obtained by eMHA and FHA are also compared. A prototype of the designed circuit was constructed. The accuracy and effectiveness of eMHA are verified by experimental measurements. This paper is accompanied by a MATLAB-based analytical tool with a graphical user interface demonstrating the effects of circuit variables on electrical quantities and waveforms. [ABSTRACT FROM AUTHOR]

Published

2020

4. Optimal Modulation for a Fifth-Order Dual-Active-Bridge Resonant Immittance DC–DC Converter.

Author

Yaqoob, Muhammad, Loo, Ka-Hong, Chan, Yiu Pang, and Jatskevich, Juri

Subjects

*AC DC transformers, *MATHEMATICAL optimization, *BRIDGE circuits, *PHASE modulation, *ELECTRIC potential

Abstract

This paper proposes a fifth-order resonant immittance network based dual-active-bridge (DAB) converter and an optimal modulation method that will ensure high-efficiency operation of the converter under wide-range variations in voltage ratio and output power level. The proposed modulation method is based on the concept of total power loss minimization, where a loss model is developed and an optimization algorithm is formulated to compute the optimal set of internal and external phase shift parameters that will lead to the maximum efficiency for a given set of operating parameters including voltage ratio and output power level. It is found that to maintain high-efficiency operation under wide-range variations in voltage ratio and output power level, the DAB converter is required to switch between different operation modes and neither soft-switching operation nor unity-power-factor operation is able to achieve wide-range high efficiency performance when used alone. The importance of $reconfigurability$ of operation mode for achieving wide-range high efficiency performance is clearly illustrated in this paper. [ABSTRACT FROM AUTHOR]

Published

2020

5. A Novel Seven-Level Active Neutral-Point-Clamped Converter With Reduced Active Switching Devices and DC-Link Voltage.

Author

Siwakoti, Yam P., Mahajan, Akshay, Rogers, Daniel J., and Blaabjerg, Frede

Subjects

*PULSE width modulation transformers, *REACTIVE power, *PASSIVE components, *ELECTRIC potential, *COST control, *SYSTEMS design

Abstract

This paper presents a novel seven-level inverter topology for medium-voltage high-power applications. It consists of eight active switches and two inner flying capacitor (FC) units forming a similar structure as in a conventional active neutral-point-clamped (ANPC) inverter. This unique arrangement reduces the number of active and passive components. A simple modulation technique reduces cost and complexity in the control system design without compromising reactive power capability. In addition, compared to major conventional seven-level inverter topologies, such as the neutral point clamped, FC, cascaded H-bridge, and ANPC topologies, the new topology reduces the dc-link voltage requirement by 50%. This recued dc-link voltage makes the new topology appealing for various industrial applications. Experimental results from a 2.2-kVA prototype are presented to support the theoretical analysis presented in this paper. The prototype demonstrates a conversion efficiency of around 97.2% ± 1% for a wide load range. [ABSTRACT FROM AUTHOR]

Published

2019

6. A Novel Segmented Component Injection Scheme to Minimize the Oscillation of DC-Link Voltage Under Balanced and Unbalanced Conditions for Vienna Rectifier.

Author

Ding, Wenlong, Qiu, Han, Duan, Bin, Xing, Xiangyang, Cui, Naxin, and Zhang, Chenghui

Subjects

*ELECTRIC current rectifiers, *OSCILLATIONS, *ELECTRIC potential, *BATTERY chargers, *PULSE width modulation

Abstract

This paper investigates a Vienna rectifier as a charger for series-connected battery packs. Focusing on carrier-based pulsewidth modulation (CBPWM), the ripple current flowing through the neutral point (NP) results in the voltage oscillation if the loads are resistive. To reduce the ripple of average NP current with mitigated distortion under balanced and unbalanced dc-link voltages conditions, a novel CBPWM with segmented component injection scheme (SCIS) is proposed in this paper. After dc component injection, continuous intervals for optimized component injection and clamping intervals for compensation component injection are identified. Optimized components are calculated originally based on unbalanced factor to make the average NP current zero-size in one switching period. Moreover, unique compensation components generate suitable NP current to shape the sinusoidal input currents according to the circuit analysis. In consequence, the SCIS not only keeps the input current with low-harmonic distortion, but also minimizes the oscillation of dc-link voltage under balanced and unbalanced conditions. In addition, the value of the NP current during the clamping intervals is analyzed under various operating conditions. The effectiveness and the performance of the proposed SCIS are verified by simulation and experiments. [ABSTRACT FROM AUTHOR]

Published

2019

7. Single-Phase Transformerless Photovoltaic Inverter With Suppressing Resonance in Improved H6.

Author

Akpinar, Eyup, Balikci, Abdul, Durbaba, Enes, and Azizoglu, Buket Turan

Subjects

*PULSE width modulation transformers, *PHOTOVOLTAIC power generation, *RESONANCE, *BIPOLAR transistors, *CAPACITORS, *ELECTRIC potential, *ELECTRIC capacity

Abstract

In low-power applications of photovoltaic (PV) systems, the transformerless grid-connected inverters have been preferred to increase the efficiency and reduce the cost, size, and power losses when they are compared to the ones with the transformer. A transformerless single-phase inverter topology with a single dc-link capacitor for the grid-connected PV systems is proposed in this paper. The proposed inverter has been simulated by using a cooperation process of the MATLAB and SPICE package programs and it has been implemented for experimental verification. The proposed inverter reduces the high-frequency common-mode leakage current caused by parasitic capacitances of PV panels, whereas it is controlled with the unipolar sinusoidal pulsewidth modulation. Also, the results show that the common-mode voltage remains constant. The efficiency of the proposed inverter has been compared to that of the most common topologies having the dc-link decoupling during the zero voltage states. This paper is accompanied by a video file demonstrating the power loss distribution in the inverter. [ABSTRACT FROM AUTHOR]

Published

2019

8. Control Strategy of DC-Link Voltage for Single-Phase Back-to-Back Cascaded H-Bridge Inverter for MV Drive With Interfacing Transformer Having Tertiary Winding.

Author

Yoo, Jeong-Mock, Jung, Hyun-Sam, and Sul, Seung-Ki

Subjects

*ELECTRIC potential, *VOLTAGE control, *CASCADE converters, *PULSE width modulation transformers, *MOTOR drives (Electric motors), *VOLTAGE-frequency converters, *REFERENCE values, *COMPUTER simulation

Abstract

This paper describes a dc-link voltage control method of a single-phase back-to-back cascaded H-bridge inverter (SBCI) for a medium-voltage motor drive system. The main advantage of the SBCI topology over the conventional regenerative cascaded H-bridge topology with a three-phase active front-end (AFE) is a simple system structure, which is composed of an input transformer, a power cell, a current sensor, etc. However, the challenging points of the SBCI are larger voltage ripple in the dc-link capacitor and imbalance of dc-link voltages of each phase. The asymmetric dc-link voltage of each power cells could cause unstable operation such as over-modulation due to the lack of the dc-link voltage of a particular phase and result in over-voltage or under-voltage faults. In this paper, the control strategy of the dc-link voltage for the SBCI that uses the negative-sequence voltage of the converter is described. The proposed control method is verified with a computer simulation whose target is a 6.6-kV–1.25-MW medium-voltage drive system. Also, through the experimental setup with the prototype SBCI whose power rating is 16.2 kVA, the dc-link voltage of each AFE has been controlled within a 0.5% error of its reference value at the full load. [ABSTRACT FROM AUTHOR]

Published

2019

9. A Modified DC Power Electronic Transformer Based on Series Connection of Full-Bridge Converters.

Author

Zhang, Jiepin, Liu, Jianqiang, Yang, Jingxi, Zhao, Nan, Wang, Yang, and Zheng, Trillion Q.

Subjects

*DIRECT currents, *POWER electronics, *ELECTRONIC transformers, *CONVERTERS (Electronics), *ELECTRIC potential, *POWER semiconductors, *POWER density

Abstract

This paper proposes a novel dc power electronic transformer (DCPET) topology for locomotive, ac/dc hybrid grid, dc distribution grid, and other isolated medium-voltage and high-power applications. Compared with conventional PET topology, the proposed DCPET has fewer power semiconductor devices and high-frequency isolation transformers, which can improve the power density and reliability. Fault handling or redundancy design can be achieved to further improve the reliability when some dc–dc modules break down. Also, input voltage sharing control can be omitted to simplify the control system and improve the stability. Meanwhile, soft switching is guaranteed for all the switches, which is beneficial to increase switching frequency and improve power density. In this paper, the principle, evolution, and control of the proposed DCPET are respectively presented and studied in detail. Finally, a prototype of the proposed DCPET is built and the experimental results verify the validity and superiority of the proposed topology. [ABSTRACT FROM AUTHOR]

Published

2019

10. Instantaneous Balancing of Neutral-Point Voltages for Stacked DC-Link Capacitors of a Multilevel Inverter for Dual-Inverter-Fed Induction Motor Drives.

Author

Yadav, Apurv Kumar, Gopakumar, K., R, Krishna Raj, Umanand, Loganathan, Matsuse, Kouki, and Kubota, Hisao

Subjects

*ELECTRIC potential, *DIRECT currents, *CAPACITORS, *ELECTRIC inverters, *INDUCTION motors

Abstract

This paper proposes a novel method for instantaneous balancing of neutral-point (NP) voltages with stacked multilevel inverters (MLIs) for variable-speed drives. The stacked MLI uses series-connected dc sources and NPs (connecting points of dc sources) to obtain the desired levels. The balancing of NP voltages are obtained by using a low-voltage-capacitor-fed cascaded H-bridge (CHB) per phase of a symmetrical six-phase induction machine (IM), which ensures zero current drawn from NPs (at any given instant). Since no current is drawn from NPs, the single dc-link operation with stacked capacitors is also possible. The scheme is suitable for applications, where low-voltage dc sources and batteries are stacked to form a dc link. A variable-speed operation is done using a seven-level inverter scheme for a symmetrical six-phase IM, which is formed by three dc-link stacked capacitors cascaded with two low-voltage-capacitor-fed CHBs per phase. Furthermore, the method is extended for an open-end IM to obtain a seven-level common-mode eliminated space vector structure using a single dc link. The generalization of this method for any stacked $n$ -level inverter without NP voltage deviation is also presented in this paper. The experimental results and analysis are included to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

11. Gate Control Optimization of Si/SiC Hybrid Switch for Junction Temperature Balance and Power Loss Reduction.

Author

Wang, Jun, Li, Zongjian, Jiang, Xi, Zeng, Cheng, and Shen, Z. John

Subjects

*METAL oxide semiconductor field-effect transistors, *ELECTRIC potential, *ZERO voltage switching, *THERMAL conductivity, *ELECTRIC fields

Abstract

The hybrid switch concept of paralleling a higher-current main Si IGBT and a lower-current auxiliary SiC mosfet offers an improved cost/performance tradeoff in power converters. Currently, the gate control strategy of these two internal devices emphasizes on minimizing the total power loss, and is referred to as the efficiency control mode in this paper. However, there is a serious risk of overheating and reliability degradation of the SiC mosfet if solely relying on this control strategy. In this paper, we propose a new method of gate control optimization, referred to as the thermal balance control mode, to keep the junction temperature of both devices within the specified temperature range, and to minimize the total power loss simultaneously. We first investigate the dependency of the hybrid switch switching losses on the gate control pattern both theoretically and experimentally. We then extensively study control optimization in these two distinct control modes in a dc–dc boost converter. It is found that the thermal balance control mode can achieve almost the same total power loss as the efficiency control mode, but much lower and more balanced junction temperatures of the two internal devices. Experimental results demonstrate that the Si/SiC hybrid switch in an optimal thermal balance control mode can achieve a 163% higher power handling capability in the 20-kHz boost converter or four times higher switching frequency in the 4-kW boost converter than a single IGBT solution with hard switching condition, and yet a considerably lower component cost than a single SiC mosfet solution in the boost converter. [ABSTRACT FROM AUTHOR]

Published

2019

12. A High-Efficiency Single-Phase T-Type BCM Microinverter.

Author

Zhang, Zhen, Zhang, Junming, Shao, Shuai, and Zhang, Junjun

Subjects

*ELECTRIC inverters, *LOAD flow analysis (Electric power systems), *ELECTRIC potential, *TRANSISTORS, *ELECTRIC power distribution grids

Abstract

This paper proposes a high-efficiency single-phase T-type boundary conduction mode (BCM) microinverter. The conventional full-bridge BCM microinverter has achieved zero voltage switching (ZVS) and thereby improved the efficiency, but it suffers from high switching losses under light load conditions. The proposed T-type BCM microinverter reserves ZVS and uses a multilevel technique to further decrease the switching losses. The BCM operation with multilevel technique will have too low switching frequency when the grid voltage approaches half of the dc link voltage. To solve this problem, this paper adopts a third operation mode for the T-type switching leg to maintain the switching frequency above a minimum value. The corresponding mode transitions are also detailed to ensure a smooth operation. Because of the turn-offdelay of the freewheeling transistor, the actual lower current boundary deviates from the programmed one, which will distort output current. To address this issue, this paper also proposes a boundary compensation method. A prototype has been built for performance verification, which can test both full-bridge and T-type topology. Compared with the full-bridge BCM microinverter, the proposed T-type BCM microinverter has a higher efficiency over the whole load range. [ABSTRACT FROM AUTHOR]

Published

2019

13. Inner Supply Data Transmission in Quasi-Resonant Flyback Converters for Li-Ion Battery Applications Using Multiplexing Mode.

Author

Min, Geon-Hong and Ha, Jung-Ik

Subjects

*MULTIPLEXING, *DATA transmission systems, *LITHIUM-ion batteries, *BATTERY chargers, *ELECTRIC potential, *CONVERTERS (Electronics)

Abstract

This paper proposes data transmission method between primary and secondary of the flyback converter without additional communication circuit while simultaneously transferring power. In some application such as a battery charger, the data exchanges between the primary and secondary sides are necessary. In the conventional system, an additional line or wireless communication modules is used for data exchanges, thereby increasing the system and connector size. The proposed system, in comparison, does not use additional signal transceiver but instead exchanges data by simply alternating operation mode of the flyback converter, thus adding communication function while not increasing the volume of the terminal and overall system. The waveform of transformer voltage is used to count the number of resonant pulses, which is used for decoding and encoding the data packet. Bidirectional communication between primary and secondary sides is possible while power is transferred to the output using an appropriate communication protocol. This paper proposes data transmission method for both single output and the multioutput cases. Also, both half-duplex and full-duplex communication using the proposed method is explained. The experimental results are presented to verify the performance of the proposed communication method. [ABSTRACT FROM AUTHOR]

Published

2019

14. A Soft-Switching Step-Down PFC Converter With Output Voltage Doubler and High Power Factor.

Author

Hosseinabadi, Farzad and Adib, Ehsan

Subjects

*CONVERTERS (Electronics), *ELECTRIC potential, *ELECTRIC power factor, *SEMICONDUCTOR devices, *HARMONIC distortion (Physics)

Abstract

In this paper, a new soft-switching bridgeless single-phase power factor correction (PFC) converter is presented and analyzed. Employing an auxiliary switch, the input current dead angle that is the main drawback of the existing buck-type PFCs is omitted, and thus, the power factor (PF) is improved, which is the main contribution of the paper. Proposed PFC converter operates under discontinuous conduction mode (DCM) and draws sinusoidal input current from power supply inherently. All switches and diodes are turnedonandoffunder soft switching, which leads to low switching losses and elimination of diode reverse recovery problems. Also, minimum numbers of semiconductor devices are in the power flow path that reduce the conduction losses. A 120-W laboratory prototype is implemented and experimental results verify the validity of theoretical analysis and show efficiency of 92.1%. In addition, total harmonic distortion (THD) of 3.3% is achieved and the input current harmonics complies with IEC61000-3-2 Class D requirements. [ABSTRACT FROM AUTHOR]

Published

2019

15. A Fast-Dynamic Unipolar Switching Control Scheme for Single-Phase Inverters in DC Microgrids.

Author

Pokharel, Mandip, Hildebrandt, Nicolai, Ho, Carl Ngai Man, and He, Yuanbin

Subjects

*MICROGRIDS, *SINGLE-phase flow, *ELECTRIC inverters, *ELECTRIC potential, *ELECTRIC currents

Abstract

This paper presents the digital implementation of a boundary controller with unipolar switching characteristic for single-phase voltage source full-bridge inverters. This paper expands the application of a second-order switching surface-based control method to unipolar switching of single-phase voltage source inverters (VSIs) using a finite-state machine. The finite-state machine has been formulated considering four different states of the inverter; positive,zero1, negative, andzero2. The second-order boundary control governs the current state of the system and provides proper switching action to keep the system within the desired reference. The control law is implemented digitally in F28m35x digital control card. A full-bridge inverter topology is used to achieve the three-level voltage switching. Various simulations and experiments were performed in a 550 VA, 120 V, 60 Hz VSI with a digitally implemented controller to verify the theoretical predictions. A high-quality voltage output was obtained for various loading conditions. The transient performance of the controller was investigated using a reference and load changes. A comparison of the implementation was made with the existing classical controllers to verify the fast-dynamic response of the system. [ABSTRACT FROM AUTHOR]

Published

2019

16. Study on a High Voltage Gain SEPIC-Based DC–DC Converter With Continuous Input Current for Sustainable Energy Applications.

Author

Ardi, Hossein and Ajami, Ali

Subjects

*ELECTRIC potential, *CONVERTERS (Electronics), *DIRECT currents, *RENEWABLE energy sources, *ELECTRIC circuits, *ELECTRIC inductors

Abstract

A high step-up dc–dc converter is proposed in this paper. The presented converter benefits from some advantages such as high voltage gain and continuous input current, which makes it suitable for the renewable energy applications. The presented converter is based on the SEPIC converter. However, the converter voltage gain is improved by employing a coupled inductor and two voltage multipliers. A passive clamp circuit is also added to the proposed converter that increases the voltage gain and reduces the voltage stress on the main switch. Thus, a switch with low $R_{{\text{DS(on)}}}$ will be needed that decreases the conduction loss. Besides, the voltage stress on the output diode in the proposed converter is reduced, which alleviates reverse recovery problem. The steady-state analysis of the proposed converter is discussed in this paper. The analysis is verified with experimental results under the output power of 245 W. [ABSTRACT FROM AUTHOR]

Published

2018

17. An Alternative IPT Pickup Controller for Material Handling Using a Current Doubler.

Author

Beh, Hui Zhi, Neath, Michael, Boys, John T., and Covic, Grant A.

Subjects

*INDUCTIVE power transmission, *MATERIALS handling, *ELECTRIC controllers, *VOLTAGE doublers, *ELECTRIC potential

Abstract

Inductive power transfer systems deployed in material handling have traditionally used parallel-tuned (current-sourced) boost regulators to independently control and regulate the load on each secondary. This paper evaluates the current doubler as an alternative parallel-tuned secondary controller within this application to better match the current and voltage requirements in the secondary resonant tuning network in high-power applications. This enables designs that enable the secondary magnetic pickup to achieve a smaller profile and fit within typical space constraints of material-handling vehicles. This paper presents the design approach needed for this regulator and compares its operation and performance against a traditional boost controller using both the simulation and the measurement of two built 5-kW secondary regulators. The current doubler naturally achieves a lower output ripple due to its interleaved switching and is found to have a comparable efficiency to the boost controller but requires slightly more components. [ABSTRACT FROM AUTHOR]

Published

2018

18. Novel Discontinuous PWM Method for a Single-Phase Three-Level Neutral Point Clamped Inverter With Efficiency Improvement and Harmonic Reduction.

Author

Lee, June-Seok, Kwak, Raeho, and Lee, Kyo-Beum

Subjects

*ELECTRIC inverters, *HARMONIC distortion (Physics), *ELECTRIC distortion, *PULSE width modulation, *ELECTRIC potential

Abstract

This paper proposes a novel discontinuous pulse-width modulation (DPWM) method to reduce the current harmonics and improve the system efficiency for a single-phase three-level neutral-point clamped inverter. In single-phase inverters, the unipolar pulse-width modulation (UP-PWM) method is commonly used. However, this method has the disadvantage of power losses due to numerous switching operations. Conventional DPWM methods reduce the power losses and improve efficiency but increase the current total harmonic distortion (THD). To overcome these weaknesses, this paper proposes a hybrid DPWM switching method combining two PWM methods: the UP-PWM method and the conventional DPWM method called one-pole clamped PWM method. Since the proposed DPWM method offers all the advantages of both PWM methods, the optimal performance—with regard to the power losses and current THD—is obtained. The combination of two PWM methods is investigated by analyzing the power losses and current THD. Based on the analysis, the process determining the optimal operating condition is introduced. The effectiveness of the proposed DPWM method is demonstrated through simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2018

19. A New PV Converter for a High-Leg Delta Transformer Using Cooperative Control of Boost Converters and Inverters.

Author

Yamaguchi, Daiki and Fujita, Hideaki

Subjects

*PHOTOVOLTAIC cells, *CONVERTERS (Electronics), *ELECTRIC inverters, *PHOTOVOLTAIC power generation, *ELECTRIC current converters

Abstract

This paper proposes a new high-efficiency photovoltaic (PV) converter for grid connection through a high-leg delta transformer. The converter is composed of a symmetrically connected boost converter and three half-bridge inverters. One of the three half-bridge inverters is connected to the boost converter, and the others are directly connected to the PV terminals. As a result, this circuit configuration enables to reduce the power losses in both boost converter and inverters. This paper also proposes a new cooperative control method between the symmetrically connected boost converter and inverter. The control method can reduce the average switching frequency to 75% of that in a conventional one, resulting in a great reduction in the switching power loss. Experimental results confirm that the proposed circuit configuration makes it possible to improve its European efficiency from 91.6% to 94.5%. Moreover, system performance is evaluated on the assumption of maximum power point tracking operation. [ABSTRACT FROM AUTHOR]

Published

2018

20. A Reduced Switch Count Single-Stage Three-Phase Bidirectional Rectifier With High-Frequency Isolation.

Author

Baranwal, Rohit, Iyer, Kartik V., Basu, Kaushik, Castelino, Gysler F., and Mohan, Ned

Subjects

*PLUG-in hybrid electric vehicles, *CASCADE converters, *ELECTRIC potential, *ELECTRIC currents, *AUTOMATIC control systems

Abstract

Dual active bridge (DAB) based converters offer the benefit of smaller volume due to high-frequency isolation and controllability of active power flow, making them attractive for various applications, such as renewable energy generation, plug-in hybrid vehicles, and distribution systems. This paper presents a novel converter topology along with a modulation strategy for a DAB-based three-phase ac to dc converter. The major benefits are single-stage conversion, no unreliable intermediate dc-link capacitor, reduced number of switches, i.e., only two active switches on the ac side, simple control scheme, open-loop unity power factor operation, bidirectional power flow, and partial soft-switching. This paper presents the analysis of all the operating modes of the converter, resulting in the analytical estimation of power transfer and rms winding current and investigation of soft-switching conditions for the power devices. Simulation and experimental results have been presented to demonstrate the advantages of the proposed technique and accuracy of the analysis.1 [ABSTRACT FROM AUTHOR]

Published

2018

21. A Comparison on Finite-Set Model Predictive Torque Control Schemes for PMSMs.

Author

Sandre-Hernandez, Omar, Rangel-Magdaleno, Jose, and Morales-Caporal, Roberto

Subjects

*TORQUE control, *GATE array circuits, *ELECTRIC potential, *PREDICTIVE control systems, *COST functions

Abstract

This paper introduces the comparison of four predictive torque control schemes for a permanent-magnet synchronous machine (PMSM). The first method is the finite-set model predictive control (FS-MPC). In FS-MPC, the optimal switching state is selected based on the evaluation and minimization of a cost function for all possible voltage space vectors (VSVs) of the inverter. The second method performs a simplified FS-MPC where the selection and evaluation of the possible VSVs are reduced to only three. The third method is based on the principle of predictive direct torque control (PDTC), where the duty cycle of the switching state is optimized for application in the inverter. Finally, a method that combines FS-MPC and PDTC named model predictive torque control is presented. This paper introduces the methodology and the results of a comprehensive comparison of the four predictive schemes based on different criterions. The control schemes are implemented on a field-programmable gate array and are applied to a PMSM. Experimental results are presented to validate the presented comparison and discussion. [ABSTRACT FROM AUTHOR]

Published

2018

22. Dynamic Control and Performance of a Dual-Active-Bridge DC–DC Converter.

Author

Takagi, Kazuto and Fujita, Hideaki

Subjects

*CASCADE converters, *DIRECT currents, *PHASE-shifting interferometry, *PHASE shifters, *MAGNETIC flux, *ELECTRIC potential, *CONTINUOUS functions

Abstract

This paper discusses dynamic behavior of a dual-active-bridge (DAB) dc–dc converter. Conventional phase-shift control methods for the DAB converter may cause dc offsets in both inductor current and transformer magnetizing current in transient states. The dc offset in the inductor current would introduce an excessive peak current through the switching devices. The dc offset in the magnetizing current may induce magnetic-flux saturation. Conventional methods simultaneously turn on and off the diagonal switches in each H-bridge converter and produce a square-wave voltage with a 50% duty ratio. In contrast, the proposed method in this paper independently controls each switch to modify the duty ratio in transient states. This paper clearly derives the requirements of each switch to eliminate the dc offsets in both currents with a settling time shorter than half the switching period. Experimental results using a 5-kW 20-kHz system verify the validity of the proposed control method, which is effective not only in a single step change, but also in a continuous change in the phase-shift reference. [ABSTRACT FROM AUTHOR]

Published

2018

23. Improved Modulation Mechanism of Parallel-Operated T-Type Three-Level PWM Rectifiers for Neutral-Point Potential Balancing and Circulating Current Suppression.

Author

Sun, Kai, Lin, Xiang, Li, Yunwei, Gao, Yucheng, and Zhang, Li

Subjects

*PULSE width modulation transformers, *ELECTRIC current rectifiers, *PARALLEL electric circuits, *FLUCTUATIONS (Physics), *ELECTRIC potential

Abstract

In high-power applications, parallel-operated T-type three-level pulse width modulation (PWM) rectifiers (T3LPRs) are widely employed to improve the power capacity and system reliability. For parallel-operated T3LPRs, there are two important issues need to be properly addressed: 1) the neutral-point potential (NPP) balancing, and 2) the zero sequence circulating current (ZSCC) between the common ac and dc bus. In this paper, the fluctuation of NPP in a T3LPR and the generative mechanism of ZSCC in parallel-operated T3LPRs are first investigated. The zero sequence voltage (ZSV) difference between the parallel-operated T3LPRs is identified as the main excitation source of the ZSCC problem. Meanwhile, the disconnection of the neutral point and the control effect difference of NPP balancing in each T3LPR also affect the ZSCCs within the parallel-operated T3LPRs. To adjust the ZSV of T3LPRs, the dwell time of the positive small voltage vector in each switching period of the converter, which is usually adjusted to balance the NPP, is also required to be controlled to suppress ZSCC. Therefore, in this paper, to avoid the possible conflict, an improved modulation mechanism is designed to guarantee simultaneous ZSCC suppression and NPP balancing. The neutral points of each T3LPR are connected. Then, by adjusting the dwell time of the positive small voltage vector, the charging time of two dc capacitors is adjusted to balance the NPP, and the ZSV differences between different T3LPRs are adjusted to suppress ZSCCs. To avoid the control effect difference of independent NPP balancing in different T3LPRs, all T3LPRs share the same value marking the difference between two dc capacitor voltages. Thus, a communication with a greatly reduced baud rate requirement is needed for NPP balancing to transfer the difference between the two dc capacitor voltages. Moreover, no extra circuit is needed for ZSCC suppression. These approaches make the proposed improved space vector PWM strategy much more practical and easy to employ. The proposed method is verified with experiments on two 3-kW T3LPR prototypes. [ABSTRACT FROM AUTHOR]

Published

2018

24. Instantaneous Phase Voltage Sensing in PWM Voltage-Source Inverters.

Author

Schubert, Michael and De Doncker, Rik W.

Subjects

*PULSE width modulation transformers, *ELECTROMECHANICAL devices, *ROTORS, *ELECTRIC potential, *POWER electronics, *ELECTRIC filters

Abstract

The output voltage of power electronic converters is a very important quantity for dynamic control of power electronic systems. In electrical drives without electromechanical position or speed sensor, the terminal reference voltage is used to obtain the rotor position. Dead-time effects and semiconductor voltage drop lead to distortion in the actual output voltage and degrade the control performance when the back electromotive force magnitude is low. Thus, for stable low-speed operation, output voltage sensing becomes necessary. Due to the switching nature of power electronic systems, this is not a trivial task, especially when instantaneous measurement of the terminal voltage is required. In this paper, an instantaneous switching-period average voltage sensing technique is proposed that utilizes a combined approach of oversampling and filtering. Based on the theoretical analysis of the sampling- and filter-induced measurement distortion, a general solution for an optimal filter design is derived. The additional sensing circuit is integrated into the low-side gate driver of the converter outputs. This paper includes details about the hardware implementation and extensive verification measurements. [ABSTRACT FROM AUTHOR]

Published

2018

25. A Single-Phase Single-Stage Switched-Boost Inverter With Four Switches.

Author

Nguyen, Minh-Khai and Tran, Tan-Tai

Subjects

*ELECTRIC inverters, *ELECTRIC switchgear, *ELECTRIC potential, *ELECTRIC power conversion, *PULSE width modulation

Abstract

This paper proposes a new single-phase single-stage switched-boost inverter with four switches. Like the quasi-Z-source inverter and quasi-switched boost inverter (qSBI), the proposed inverter has the main features as continuous input current, buck/boost voltage with single-stage conversion, and shoot-through immunity. Compared to the qSBI, the proposed inverter uses one more capacitor and one less switch. This paper presents the operating principles, pulse-width modulation control strategy, parameter design guidelines, and simulation results for the proposed inverter. To verify the performance of the proposed inverter, an 800-W prototype was built with an 110 V/50 Hz output voltage in stand-alone and grid-connected modes. The simulation and experimental results matched those of the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2018

26. Voltage-Lift Technique Based Nonisolated Boost DC–DC Converter: Analysis and Design.

Author

Mohammadzadeh Shahir, Farzad, Babaei, Ebrahim, and Farsadi, Murtaza

Subjects

*ELECTRIC potential, *DIRECT currents, *CONVERTERS (Electronics), *MEMBRANE potential, *DISCONTINUOUS functions, *ELECTRIC inductors

Abstract

In this paper, a new structure of nonisolated boost dc–dc converters based on voltage-lift technique is proposed. In comparison with conventional nonisolated boost dc–dc converters, the proposed converter generates higher voltage gain. In this paper, the relations between voltage and current of all elements in continuous conduction mode and discontinuous conduction mode are calculated as well as voltage gain in each mode. Then, the critical inductance and stress of switch current are extracted. Finally, the validity of given theories is examined by using the experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

27. A Bidirectional Resonant DC–DC Converter Suitable for Wide Voltage Gain Range.

Author

Shen, Yanfeng, Wang, Huai, Al-Durra, Ahmed, Qin, Zian, and Blaabjerg, Frede

Subjects

*ELECTRIC network topology, *ENERGY storage, *DC-to-DC converters, *CASCADE converters, *ELECTRIC potential, *ZERO voltage switching, *ANALYTICAL solutions

Abstract

This paper proposes a new bidirectional resonant dc–dc converter suitable for wide voltage gain range applications (e.g., energy storage systems). The proposed converter overcomes the narrow voltage gain range of conventional resonant dc–dc converters, and meanwhile achieves high efficiency throughout the wide range of operation voltage. It is achieved by configuring a full-bridge mode and a half-bridge mode operation during each switching cycle. A fixed-frequency phase-shift control scheme is proposed and the normalized voltage gain can be always from 0.5 to 1, regardless of the load. The transformer root-mean-square (rms) currents in both the forward and reverse power flow directions have a small variation with respect to the voltage gain, which is beneficial to the conduction losses reduction throughout a wide voltage range. Moreover, the power devices are soft-switched for minimum switching losses. The operation principles and characteristics of the proposed converter are firstly analyzed in this paper. Then the analytical solutions for the voltage gain, soft-switching, and rms currents are derived, which facilitates the parameters design and optimization. Finally, the proposed topology and analysis are verified with experimental results obtained from a 1-kW converter prototype. [ABSTRACT FROM PUBLISHER]

Published

2018

28. Evaluation of Carrier-Based Modulation Techniques With Common-Mode Voltage Reduction for Neutral Point Clamped Converter.

Author

Tsai, Meng-Jiang, Chen, Hsin-Chih, Tsai, Meng-Ru, Wang, Yao-Bang, and Cheng, Po-Tai

Subjects

*PULSE width modulation, *ELECTRIC potential, *HYBRID electric vehicles, *PASSIVE optical networks

Abstract

Common-mode voltage output is closely associated with switching states in three-phase three-wire neutral point clamped converter. Detailed analysis shows avoiding redundant states can effectively improve the common-mode voltage, so this paper proposes a pulse width modulation (PWM) technique with zero redundant state to reduce the common-mode voltage output, and evaluates their performance with the conventional PWM schemes. This paper also takes the compensation of neutral point potential deviation into consideration. Laboratory test results are presented to verify the effectiveness of the proposed scheme. [ABSTRACT FROM PUBLISHER]

Published

2018

29. Modulation Techniques for Enhanced Reduction in Common-Mode Voltage and Output Voltage Distortion in Indirect Matrix Converters.

Author

Padhee, Varsha, Sahoo, Ashish Kumar, and Mohan, Ned

Subjects

*PULSE width modulation, *ELECTRIC potential, *MATRIX converters, *ELECTRIC filters

Abstract

This paper targets the reduction of common-mode voltage in an indirect matrix converter (IMC) through an intelligent space-vector-based modulation technique. This mode of control results in lower dV/dt at the motor terminals, thereby, reducing voltage stress to windings; and reduced output voltage distortion resulting in lower machine losses. The conventional indirect space vector pulse-width modulation method of controlling matrix converters involves independent control of either the rectifying stage or the inverting stage of the converter. However, in this paper, by suitable selection of space vectors, the rectifying stage of the matrix converter generates different levels of virtual dc-link voltage. Therefore, the responsibility of formulating output voltages with a particular magnitude and frequency, which can be translated to different machine speeds, has been transferred solely to the rectifying stage of the IMC. Estimation of the degree of distortion in the three-phase output voltage is another facet discussed in this paper, which aids the sizing and designing of output passive filters. The analysis of output voltage distortion and the proposed modulation strategies have been substantiated by simulations in MATLAB/Simulink and experimentally verified on a scaled down laboratory prototype. [ABSTRACT FROM AUTHOR]

Published

2017

30. Sensor-Less Current Sharing Over Wide Operating Range for Extended-Duty-Ratio Boost Converter.

Author

Roy, Jinia and Ayyanar, Raja

Subjects

*ELECTRIC currents, *CASCADE converters, *ELECTRIC potential, *ELECTRIC properties of gallium nitride, *CAPACITORS

Abstract

An extended-duty-ratio (EDR) boost converter is studied extensively in this paper for high voltage gain applications with a wide input (and/or output) voltage range. The EDR is a unique combination of an interleaved, multiphase boost converter and switched capacitor configuration that achieves high voltage gain with significantly lower switch voltage stress and switching losses compared to conventional high-gain solutions. Most of the switches in the multiphase EDR experience only a fixed fraction of the output voltage ($1/M, 2/M$ , etc., where $M$ is the number of phases). Through extensive analysis over a wide operating range, it is shown here that the EDR boost converter has inherent current sharing among the phases only in a limited range of duty ratio— $(M-1)/M \leq D \leq 1$. As the duty ratio reduces beyond this range as required in wide input voltage applications, inherent current sharing property is lost. In this paper, techniques to ensure current sharing under all operating zones without requiring current sensors are presented. Instead of having equal duty ratio for each phase, it is adjusted for each phase according to the operating region of the converter. Extensive analysis is presented to derive the required duty ratio changes for the different phases. The proposed concept is validated with experimental results from a 250 W, 3-phase EDR boost, and GaN-based hardware prototype. [ABSTRACT FROM AUTHOR]

Published

2017

31. A Single-Stage Two-Switch PFC Rectifier With Wide Output Voltage Range and Automatic AC Ripple Power Decoupling.

Author

Li, Sinan, Qi, Wenlong, Tan, Siew-Chong, and Hui, S. Y. Ron

Subjects

*ELECTRIC current rectifiers, *ELECTRIC power factor, *ELECTROLYTIC capacitors, *ELECTRIC potential, *ALTERNATING currents

Abstract

Conventional single-phase power-factor-correction (PFC) rectifiers with active power decoupling capability typically require more than three active switches in their circuits. By exploring the concept of power-buffer cell, a new single-stage PFC rectifier with two active switches, one inductor and one small power-buffering capacitor is reported in this paper. The proposed converter can achieve high-power factor, wide output voltage range, and power decoupling function without using electrolytic capacitor. Additionally, an automatic power decoupling control scheme that is simple and easy to implement is proposed in this paper. The operating principle, control method, and design considerations of the proposed rectifier are also provided. A 100-W prototype with ac input voltage of 110 Vrms and a regulated dc output voltage ranging from 30 to 100 V has been successfully designed and practically tested. The experimental results show that with only a 15 μF power-buffering film capacitor, the proposed converter can achieve an input power factor of over 0.98, peak efficiency of 93.9%, and output voltage ripple of less than 3%, at 100-W output power. [ABSTRACT FROM PUBLISHER]

Published

2017

32. A Novel STATCOM Based on Diode-Clamped Modular Multilevel Converters.

Author

Liu, Xiangdong, Lv, Jingliang, Gao, Congzhe, Chen, Zhen, and Chen, Si

Subjects

*CASCADE converters, *ELECTRIC current converters, *ROTARY converters, *POWER capacitors, *ELECTRIC potential

Abstract

A new static synchronous compensator (STATCOM) based on the diode-clamped modular multilevel converter (DCM2 C) is proposed in this paper. In this converter topology, the capacitor voltage is clamped by using a low power rating diode in each submodule. The quantity of voltage sensors is significantly reduced and is free from the number of voltage levels. Furthermore, the voltage balancing control method becomes very simple and the capacitor voltage balance speed is fast. Based on the structure of modular multilevel converter, the DCM2C-STATCOM has the capability of Var compensation and negative-sequence current compensation. The topology characteristics and compensation control method of DCM2C-STATCOM are investigated in this paper. Experimental results obtained from a laboratory prototype validate that the capacitor voltage of the proposed DCM2C-STATCOM can be well balanced and the Var and negative-sequence current compensations are effective. [ABSTRACT FROM AUTHOR]

Published

2017

33. An Improved Three-Phase Buck Rectifier Topology With Reduced Voltage Stress on Transistors.

Author

Lei, Jiaxing, Feng, Shuang, Zhao, Jianfeng, Chen, Wu, Wheeler, Patrick, and Shi, Mingming

Subjects

*TRANSISTORS, *ELECTRIC potential, *TOPOLOGY, *ELECTRIC current rectifiers, *DIODES

Abstract

The three-phase buck rectifier (3ph-BR) is suitable for applications where a voltage step-down function is required. In this paper, an improved 3ph-BR topology is proposed to reduce the voltage stress on the transistors. The freewheeling diode in the conventional topology is split into two diodes in series and the input neutral point is connected to the common point of the two diodes. With the proposed topology and the corresponding modified modulation scheme, the transistors only need to withstand the input phase voltage instead of the line-to-line voltage, bringing about the significant reduction of voltage stress. The proposed topology enables a more cost-efficient and flexible selection of the transistors. Experimental results have verified the validity of the modified topology and associated modulation scheme. [ABSTRACT FROM AUTHOR]

Published

2020

34. Design of Passive Common-Mode Attenuation Methods for Inverter-Fed Induction Motor Drive With Reduced Common-Mode Voltage PWM Technique.

Author

Jayaraman, Kalaiselvi and Kumar, Manish

Subjects

*INDUCTION motors, *PULSE width modulation transformers, *INDUCTION machinery, *VECTOR spaces, *PASSIVE components, *PULSE width modulation inverters, *ELECTRIC potential

Abstract

This paper investigates the influence of active zero vector pulsewidth modulation (AZPWM-1) and space vector pulsewidth modulation (SVPWM) on the design of passive common-mode (CM) attenuation methods to reduce CM current and shaft voltage in inverter-fed V/f-controlled induction motor drives. The passive CM attenuation methods examined here are the CM choke, the CM electromagnetic interference (EMI) filter, and the CM transformer. The attenuation requirement of AZPWM-1 and SVPWM is identified to design the passive CM choke and EMI filter. Based on the attenuation requirement, the design guidelines are revisited for SVPWM, and design rules are proposed for AZPWM-1. However, the CM transformer is designed based on the step change in magnitude of CM voltage of both the pulsewidth modulations (PWMs). The limitations in design, regarding switching frequency and component size for each case, are also established. It is shown that to have a similar attenuation in the considered two PWM cases, AZPWM-1 requires smaller passive components compared to SVPWM. The proposed design guidelines are substantiated with experimental results on a 1.1-kW induction motor drive. [ABSTRACT FROM AUTHOR]

Published

2020

35. An Active Capacitor Voltage Balancing Method for Seven-Level Hybrid Clamped (7L-HC) Converter in Motor Drives.

Author

Tian, Hao and Li, Yun Wei

Subjects

*CAPACITORS, *ELECTRIC potential, *VARIABLE speed drives

Abstract

Multilevel converters are widely applied in medium voltage (MV) drive systems due to the attractive features, such as the ability to use devices with lower voltage ratings, high equivalent switching frequency, etc. Recently, a multilevel topology, named seven-level hybrid clamped (7L-HC), is proposed for MV drives. It has a competitive number of devices, showing the potential to build low-cost 7L converters. However, to ensure the wide frequency range operation and power quality of MV drives, its dc-link capacitors and floating capacitors must be controlled properly with balanced voltages. In this paper, an active voltage balancing method is proposed for the 7L-HC converter. This method can effectively balance all the capacitor voltages under a wide frequency range. The method is embedded in the PWM procedure without modifying the control strategies. Simulation and experimental results are provided to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

36. A Hybrid Cockcroft–Walton/Dickson Multiplier for High Voltage Generation.

Author

Park, Sanghyeon, Yang, Jun, and Rivas-Davila, Juan

Subjects

*VOLTAGE multipliers, *ON-chip charge pumps, *ELECTRIC potential, *SWITCHED capacitor circuits, *LOW voltage systems, *HIGH voltages, *TRIBOELECTRICITY

Abstract

This paper presents a voltage multiplier topology that is a hybrid between a Cockcroft–Walton multiplier and a Dickson charge pump. The Cockcroft–Walton structure exhibits significant output voltage drop under load as the number of multiplier stage increases. This is because all coupling capacitors are connected in series. Dickson charge pump mitigates this issue by connecting all capacitors in parallel. But this solution comes at the expense of large capacitor voltage stress at the last multiplier stage. The proposed hybrid structure arranges some capacitors in parallel and others in series, thereby achieving low output voltage drop and low capacitor voltage stress at the same time. We develop a model that predicts hybrid multiplier's performance and validates it experimentally. We also demonstrate a 60–2.25 kV dc–dc converter based on a 16-stage hybrid voltage multiplier which achieves a voltage gain of 12.8 while keeping the highest capacitor voltage stress to 660 V. [ABSTRACT FROM AUTHOR]

Published

2020

37. Simple and Affordable Method for Fast Transient Measurements of SiC Devices.

Author

Garrido, David, Baraia-Etxaburu, Igor, Arza, Joseba, and Barrenetxea, Manex

Subjects

*STRAY currents, *ENERGY dissipation, *ELECTRIC potential, *ELECTRIC potential measurement, *ELECTRIC inductance

Abstract

The measurement of fast voltage and current transients of Silicon Carbide (SiC) devices requires high bandwidth (BW) probes. Commercially available voltage and current probes can be expensive, and, in addition, the delay introduced by them must be compensated to achieve a proper time alignment (de-skew). Determining this de-skewing value is not a trivial task. In this paper, a simple and affordable measurement method is presented for the simultaneous measurement of the voltage and current transients of SiC devices. The voltage is measured by means of a high BW RC attenuator, while the current is estimated from the voltage drop in the stray inductance of the switching loop. Since both voltages are measured with two equal and matched high BW passive voltage probes, there is no need to apply any de-skew. This is one of the most important advantages of the method. The presented method is experimentally evaluated and used for the estimation of energy switching losses in the tested SiC-mosfet. [ABSTRACT FROM AUTHOR]

Published

2020

38. A Novel Space-Vector Modulation Method for Nine-Switch Converter.

Author

Pan, Lei, Zhang, Junru, Zhang, Jingmei, Pang, Yi, Wang, Beibei, Wang, Kai, and Xu, Dongxing

Subjects

*TORQUE control, *FREQUENCY changers, *POWER electronics, *SUPPORT vector machines, *HARMONIC distortion (Physics)

Abstract

Nine-switch converter (NSC) has been presented as a dual-output converter with common frequency (CF) or different frequency (DF) operation modes. This paper proposes a novel space-vector modulation (SVM) method for the NSC that supports both the CF and DF modes. This method is based on the simplification of the space-vector diagram of NSC into that of six-switch converter, and the SVM method for NSC can be done like conventional SSC. The proposed voltage vector selection method without using common logical xor operation and the calculation method for dwelling times of voltage vectors are described in detail. In addition, the modulation indices for two ac terminals of NSC have been analyzed deeply, and the derived fitting equations can guide engineering application. The performance of the proposed SVM is verified by the simulation and experimental results, and the low total harmonic distortions and harmonic components for phase currents prove the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

39. Variable-Parameter T-Circuit-Based IPT System Charging Battery With Constant Current or Constant Voltage Output.

Author

Chen, Yang, Li, Mingxuan, Yang, Bin, Chen, Shuxin, Li, Qiao, He, Zhengyou, and Mai, Ruikun

Subjects

*ELECTRIC potential, *PASSIVE components, *ELECTRIC batteries, *CURRENT fluctuations, *LEAD-acid batteries, *AIR gap (Engineering), *CAPACITOR switching

Abstract

Load-independent output characteristics of inductive power transfer (IPT) systems are increasingly popular in battery charging. This paper proposes a novel variable-parameter T-circuit (VT) for an IPT system charging a battery with constant current (CC) or constant voltage (CV) output. The VT can transfer a CC/CV input to a CC or CV output by using an ac switch and a passive component (inductor or capacitor). An IPT system with a VT for CC–CV charging can reduce the number of passive components and ac switches. Besides, the proposed VT merits more design freedom of charge current/voltage with the constraints imposed by the loosely coupled transformer parameters compared to that of the traditional one. In addition, there are three kinds of VTs for various IPT charging systems with different requirements. A 400 W laboratory-scale prototype with a 150 mm air gap was built to verify the theoretical analyses. Both electronic load and lead-acid battery are utilized to verify the charging profile of the proposed method. The experimental results of the IPT system indicate that the fluctuation of the charging current in CC mode is less than 2%, and the change rate of charging voltage in CV mode is within 2.9%. The maximum overall efficiency 93.93% of the charging system is achieved from a dc 110 V input to a dc 100 V output. [ABSTRACT FROM AUTHOR]

Published

2020

40. Three-Legged High-Gain Phase-Modulated DC–AC Converter for Mitigation of Device Capacitance Induced Ringing Voltage.

Author

Kummari, Nareshkumar and Chattopadhyay, Souvik

Subjects

*DC-AC converters, *ZERO current switching, *ZERO voltage switching, *ELECTRIC potential, *VOLTAGE-frequency converters, *CAPACITOR switching, *LED lighting, *CONVERTERS (Electronics)

Abstract

In this paper, a method is proposed to eliminate the voltage ringing problem in a phase-modulated dc–ac converter, also known as a micro-inverter. The basic idea is to apply a time-critical two-stepped voltage waveform to the input of the converter bridge connected to the filter inductor. This method is implemented by a new topology that has one more switching leg added to the full bridge voltage fed converter. It produces a second voltage level and adds it to the first by using a transformer. The advantages of the proposed method are as follows. It almost eliminates the requirement of a voltage clamp, there is no circulating current in the freewheeling state, and the secondary side devices have less voltage and current stress compared to a conventional phase-modulated converter. The overall benefit is an improvement in converter efficiency even for a high-voltage conversion ratio application. The proposed topology operates with a secondary side modulation scheme that achieves zero-voltage switching of four devices on the primary side and either zero-voltage switching or zero-current switching of all the devices on the secondary side, over the entire line cycle of the ac output. Finally, the experimental results verify the proposed method. [ABSTRACT FROM AUTHOR]

Published

2020

41. PWM Resonant Converter With Asymmetric Modulation for ZVS Active Voltage Doubler Rectifier and Forced Half Resonance in PV Application.

Author

Kim, Jong-Woo, Park, Moo-Hyun, Han, Jung-Kyu, Lee, Moonhyun, and Lai, Jih-Sheng

Subjects

*ELECTRIC current rectifiers, *RESONANCE, *PULSE width modulation inverters, *ELECTRIC potential, *CURRENT transformers (Instrument transformer), *PULSE width modulation

Abstract

In photovoltaic applications, many previous research works have focused on pulsewidth modulation (PWM) resonant converters in order to achieve a high efficiency with a wide input voltage range. Conventional approaches utilized symmetric boosting modulation at the secondary side rectifier to obtain a symmetric operation, and they utilized two boosting modes in a switching period. Among various rectifier structures, the voltage doubler structure has a strong advantage due to a small number of components. However, it suffers from serious hard switching losses in the secondary side rectifier. In this paper, a new converter with a novel asymmetrical modulation is proposed and verified. The strong point of the proposed converter is that it eliminates hard switching turn-on losses from the rectifier, while maintaining the minimized number of components. Although the proposed converter adopts an asymmetric modulation, the offset current on the transformer becomes zero inherently. Furthermore, a “forced half resonance” operation of the proposed converter keeps rms current stresses at the same level as conventional converter although it has a higher peak current. Accordingly, the proposed converter achieves a superior efficiency with the minimum number of components at 35–25 V input and 380 V/300 W output specification. [ABSTRACT FROM AUTHOR]

Published

2020

42. Analysis and Design of LLC Converter Considering Output Voltage Regulation Under No-Load Condition.

Author

Kim, Jong-Woo, Park, Moo-Hyun, Lee, Byoung-Hee, and Lai, Jih-Sheng

Subjects

*ELECTRICAL conductivity transitions, *ELECTRIC potential, *GOVERNMENT regulation, *RESONANT power convertors, *ELECTRIC current converters, *VOLTAGE control, *CASCADE converters

Abstract

In the no-load condition, LLC converter usually fails to regulate its output voltage although it operates at a high switching frequency. Till now, it is hard to obtain the exact relationship between design parameters and the maximum switching frequency for no-load regulation capability. In this paper, a specific criterion for no-load regulation of LLC converter is provided, without using active components or other modulation schemes. By analyzing the macroscopic switching period and microscopic switching transition in the no-load condition, it is shown that not only the peaking resonant current during the switching transition, but also the resonant tank design affect the no-load regulation of the LLC converter, which affects the no-load regulation capability. Furthermore, the relationship among design parameters is analyzed and the design guideline is also provided to achieve no-load regulation at the specified maximum switching frequency. To verify the effectiveness of the proposed design, 400 V input and 50 V/200 W output prototype is built and tested. [ABSTRACT FROM AUTHOR]

Published

2020

43. Ultra-Wide Output Voltage Range Power Supply Based on Modular Switched-Converter Principle.

Author

Lu, Yangjun, Wu, Hongfei, Tu, Bo, Li, Mengxi, Xia, Yuzheng, and Xing, Yan

Subjects

*POWER resources, *CASCADE converters, *ELECTRIC potential, *DC-to-DC converters, *BALANCE of power, *VOLTAGE control

Abstract

A systematic method for developing ultra-wide output voltage range power supply based on modular switched-converter principle is proposed in this paper. The basic symmetric switched-converter (SSC) module is composed of two dc–dc modules, two diodes, and one active switch. Multi-stage SSC modules are generated by symmetric cascaded connection method. By controlling the active switches in multi-stage SSC modules, the connections of all the dc–dc modules’ output ports can be changed flexibly among series, parallel, and partial–parallel–partial-series connections. Then segmented regulation can be realized and system output voltage range can be widely extended. Meanwhile, the voltage range of each dc–dc module can be narrowed and the voltage/current stress can be reduced to simplify the design, increase device utilization ratio, and improve overall efficiency. A full-bridge isolated buck–boost converter with a semiactive rectifier, which features soft-switching and wide voltage adjustment range, is adopted as the dc–dc module to realize the proposed system. Input current sharing control strategy is adopted to ensure proper power balancing in all possible operating modes. The stability of the proposed system is also explored. Simulation and experimental results are provided to verify the effectiveness and advantages of the proposed system configuration, the switched-converter principle, and the control strategies. [ABSTRACT FROM AUTHOR]

Published

2020

44. Analysis of the Neutral-Point Voltage Self-Balance Mechanism in the Three-Level Full-Bridge DC−DC Converter by Introduction of Flying Capacitors.

Author

Liu, Peng and Duan, Shanxu

Subjects

*CAPACITORS, *CAPACITOR switching, *ELECTRIC potential, *POWER resources, *VOLTAGE control

Abstract

The three-level full-bridge (TLFB) dc−dc converter has been widely used in high-voltage, high-power applications. In the experimental test, the neutral-point voltage deviation appears; moreover, it has also been found out that if the flying capacitors are introduced, the input capacitor voltages could realize self-balance even if no active balancing solutions are adopted. In the previous publications, the role of flying capacitors is generally considered to extend the range of soft switching; however, the self-balance ability has not been mentioned or investigated in any publications thus far. In order to fill this gap, this paper provides the detailed mode operation analysis of the TLFB converter and reveals the cause of the imbalance. In addition, the mechanism of the self-balance ability provided by the flying capacitors is explained in detail, which gives a deep insight into the converter. At last, the influence factor of the voltage error in steady state has been analyzed, and the specific expression of the voltage error is also derived. The feasibility of the theoretical analysis is verified by the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

45. Capacitor Voltage Balancing and Stabilization for 4-Level Hybrid-Clamped Converter Using Selected Switching States.

Author

Pan, Jianyu, Na, Risha, Yang, Yong, Cai, Haiwei, and Xu, Longya

Subjects

*CAPACITOR switching, *CAPACITORS, *ELECTRIC potential, *VOLTAGE control

Abstract

Without active control, the voltage fluctuations of the dc-link and flying capacitors in a 4-level hybrid-clamped converter (4L-HCC) become excessively large in low-frequency operation. This paper studies the switching state redundancy inherent in a 4L-HCC and proposes a new capacitor voltage balancing and stabilizing method to minimize the dc-link and flying capacitor voltage fluctuations. A straightforward algorithm is developed based on a logic table to select the suitable switching states. Verified by simulation and experimental testing results, the new method and algorithm virtually eliminate all the big voltage fluctuations of capacitors at low and zero frequencies, greatly enhancing the robustness and reliability of a 4L-HCC. The capacitor size can be reduced by more than 80% compared with the conventional method. [ABSTRACT FROM AUTHOR]

Published

2019

46. A Minimum Switch Five-Level Unidirectional Rectifier Without Any Voltage Balancing and Pre-Charging Circuitry.

Author

Mukherjee, Debranjan and Kastha, Debaprasad

Subjects

*ELECTRIC current rectifiers, *ELECTRIC potential, *SEMICONDUCTOR devices, *ELECTRICAL conductivity transitions, *SEMICONDUCTOR diodes, *VOLTAGE control, *THRESHOLD voltage

Abstract

This paper proposes a three-phase, five-level, non-regenerative pulsewidth modulated rectifier using only two active switches (minimum required) per phase, which drastically reduces gate driver requirement and hardware complexity. It draws sinusoidal input current at close to unity power factor. All the semiconductor devices are rated at only one fourth of the dc-link voltage, and none of them requires any transient voltage balancing snubber. A total of 8 out of the 14 diodes per phase undergo soft switching transition under all operating conditions, which increases its efficiency. No extra hardware circuitry for balancing the flying capacitors (FCs) or the dc-link mid-point voltage are required, which further reduces hardware complexity and increases the conversion efficiency. The proposed topology does not need any sophisticated startup procedure for charging the FCs either, which solves the problem of semiconductor overvoltage during starting. A 3-kW laboratory prototype is built to experimentally verify the proposed topology. The maximum efficiency obtained from the prototype is 98.7%, and it is always more than 96% for the load range from 15% to its rated. [ABSTRACT FROM AUTHOR]

Published

2019

47. Near-Unity Power Factor, Voltage Step-Up/Down Conversion Pulse-Width Modulated Switching Rectification for Wireless Power Transfer Receiver.

Author

Fan, Philex Ming-Yan and bin Mohd Daut, Mohamad Hazwan

Subjects

*WIRELESS power transmission, *ELECTRIC current rectifiers, *AC DC transformers, *ELECTRIC potential, *VOLTAGE control, *ENERGY transfer, *PULSE width modulation, *THERMOELECTRIC power

Abstract

The pulse-width modulated (PWM) switching rectification that can achieve a high power factor (PF) for increasing the energy transfer efficiency between an LC resonator and a rectifier and voltage step-up and -down conversion is proposed for a wireless power transfer (WPT) receiver. The proposed method can emulate the switching rectifier as a resistive load by using an inductor and integrated phase synchronizers. Additionally, similar to a switched-inductor converter that controls the duty cycle ratio (D), the proposed PWM rectifier can control the output voltage VOUT when the input is a rectified, wirelessly coupled voltage instead of a constant voltage. Thus, unlike a conventional PWM switching rectifier for ac mains, an additional voltage conditioning circuit would not be needed after the proposed rectifier for WPT. The proposed PWM switching rectification is implemented in the AMS 0.18 μm 1.8 V/5 V CMOS process. PF = 1 is measured, indicating the most efficient energy transfer, compared to only 0.55–0.65 in a peak detection rectifier. Additionally, 88.2% of peak power conversion efficiency of the switching rectifier is achieved, and the maximum output power is 80.3 mW at 500 kHz of the WPT frequency. Moreover, the measured voltage conversion ratios ranging between 0.73× and 2× are demonstrated in this paper. [ABSTRACT FROM AUTHOR]

Published

2019

48. A Modular Multilevel Series/Parallel Converter for a Wide Frequency Range Operation.

Author

Li, Zhongxi, Lizana F., Ricardo, Yu, Zhujun, Sha, Sha, Peterchev, Angel V., and Goetz, Stefan M.

Subjects

*FREQUENCY changers, *ELECTRIC network topology, *CONVERTERS (Electronics), *BRIDGE circuits, *POLITICAL succession, *CAPACITORS, *ELECTRIC potential, *PULSE width modulation transformers

Abstract

When providing ac output, modular multilevel converters (MMCs) experience power fluctuation in the phase arms. The power fluctuation causes voltage ripple on the module capacitors, which grows with the output power and inversely to the output frequency. Thus, low-frequency operations of MMCs, e.g., for motor drives, require injecting common-mode voltages and circulating currents, and strict dc voltage output relative to ground is impossible. To address this problem, this paper introduces a novel module topology that allows parallel module connectivity in addition to the series and bypass states. The parallel state directly transfers power across the modules and arms to cancel the power fluctuations and hence suppresses the capacitor voltage ripple. The proposed series/parallel converter can operate at a wide frequency range down to dc without common-mode voltages or circulating currents; it also allows sensorless operation and full utilization of the components at higher output frequencies. We present detailed simulation and experiment results to characterize the advantages and limitations of the proposed solution. [ABSTRACT FROM AUTHOR]

Published

2019

49. Modular Parallel Multi-Inverter System for High-Power Inductive Power Transfer.

Author

Deng, Qijun, Sun, Pan, Hu, Wenshan, Czarkowski, Dariusz, Kazimierczuk, Marian K., and Zhou, Hong

Subjects

*POLITICAL succession, *ELECTRIC inverters, *SYNCHRONIZATION, *ELECTRIC potential

Abstract

In order to provide high and extendable power levels for inductive power transfer (IPT) system, a parallel multi-inverter system based on modular inverter is presented. Various power requirements can be implemented by an adjustment of the number of paralleled inverters, which provides a high modularity. A master−slave scheme is employed for the switching-driver signals of parallel inverters, where one acts as a leader while others act as followers. Despite the master−slave scheme, the proposed circuit topology has natural robustness because of the equality in terms of the hardware configuration of each modular inverter. For proper parameters, the output phase (current lagging corresponding voltage) of an inverter is lower than the average of output phase of all inverters, when its output voltage lags behind others, and vice versa. Based on this approach, PI controllers are designed to implement phase synchronization for output voltages of all inverters. An IPT prototype supplied by the proposed parallel multi-inverter with three inverters was designed, built, and tested. Experiments show that the proposed parallel multi-inverter system has not only good circulating current suppression capacity but also excellent performance of phase synchronization. The maximum dc−dc efficiency was 94% at a 35.1 kW receiving power. This paper is accompanied by a Matlab/Simulink file demonstrating phase synchronization control. [ABSTRACT FROM AUTHOR]

Published

2019

50. Sliding-Mode Sensorless Control of PMSM With Inverter Nonlinearity Compensation.

Author

Wang, Yangrui, Xu, Yongxiang, and Zou, Jibin

Subjects

*SLIDING mode control, *WAGES, *ELECTRIC potential, *SET functions, *LEAST squares, *HARMONIC suppression filters, *RANDOM access memory

Abstract

In this paper, a robust adaptive sliding-mode observer (SMO) is designed based on the surface permanent-magnet synchronous machine (SPMSM) model in rotor reference frame ($\gamma \delta $ -axis), and an online inverter nonlinearity identification and compensation method is proposed. In order to reduce the chattering of the SMO, an adaptive law is presented to help estimate the back electromotive forces of an SPMSM; thus, smaller gains can be set for switching functions of the SMO. The small-signal model of the proposed sensorless scheme is derived for analyzing the steady-state and dynamic behavior of the sensorless scheme. Voltage distortion, caused by nonlinear characteristics of switching devices, not only causes (6k ± 1)th harmonics in phase currents but also leads to a rotor position estimation error. The equivalent amplitude of the voltage distortion can be identified based on the derived small-signal model of the proposed sensorless scheme. To improve the accuracy of the estimated voltage distortion, a recursive restricted total least squares is applied to obtain the estimated amplitude of the voltage distortion. Experimental results validate the proposed sensorless control scheme and its effectiveness. [ABSTRACT FROM AUTHOR]

Published

2019