Showing total 637 results

1. A Novel Bidirectional DC/AC Stacked Matrix Converter Design for Electrified Vehicle Applications.

Author

Mousavi Sangdehi, S. Mahdi, Hamidifar, Saeedeh, and Kar, Narayan C.

Subjects

CONVERTERS (Electronics), ELECTRIC vehicles, HYBRID electric vehicle research, POWER transmission, AC DC transformers

Abstract

In the rapidly growing field of electrified transportation technology, hybrid electric and electric vehicle (HEV/EV) manufacturers have been placing increasing demands on the designers to improve the efficiency and reduce the costs of vehicle components to sustain a niche in the EV market. To understand the significance and challenges in an efficient and economical drivetrain design, this paper presents a part of an ongoing project that aims at developing a comprehensive study on dc/ac drive motor technology in EV applications. In this paper, a new three-level three-phase matrix converter topology, along with two conventional frequently used three-level three-phase dc/ac converter topologies, namely, diode-clamped and H-bridge converters, are implemented. Furthermore, comprehensive analysis and comparative studies are conducted to examine the performance and efficiency of these converter topologies according to EV design criteria. In addition, experimental investigations are carried out on the aforementioned converter configurations to help EV designers choose the most suitable converter topology. [ABSTRACT FROM PUBLISHER]

Published

2014

2. Piecewise Linear Model for Snubberless Dual Active Bridge Commutation.

Author

Farhangi, Babak and Toliyat, Hamid A.

Subjects

ELECTRIC power conversion, BATTERY chargers, CONVERTERS (Electronics), METAL oxide semiconductor field-effect transistors, STATE-space methods

Abstract

A dual active bridge (DAB) converter promises high power density. The highest power transfer can be achieved by phase shift modulation inside the zero-voltage switching boundaries. This paper analyzes the transients of DAB commutation. Although commutation has been previously analyzed for DAB with the linear turn-off snubbers, in today's industries, the output capacitors of the switches are utilized as the snubberless approach. The presence of these time-variant capacitors leads to nonlinear equations. This paper applies a piecewise linear model for analyzing the commutation of the ac-link current into the switches. The study is inspired by practical experiments, and the results are experimentally verified. [ABSTRACT FROM PUBLISHER]

Published

2015

3. An Optimized Switching Strategy for a Ripple-Canceling Boost Converter.

Author

Soriano-Rangel, Carlos Abraham, Rosas-Caro, Julio Cesar, and Mancilla-David, Fernando

Subjects

CAPACITORS, CONVERTERS (Electronics), ELECTRIC power conversion, PULSE width modulation transformers, DIRECT currents, EQUIPMENT & supplies

Abstract

A hybrid switched-capacitor/interleaved boost converter able to provide a high voltage gain and to cancel the input current ripple at a preselected duty cycle was recently presented in the literature. This paper extends that work by proposing an optimized switching strategy for operating conditions at other values of duty cycle. The switching strategy effect on the converter's voltage gain and input current ripple is quantified and compared against the performance under the conventional switching strategy. The approach is validated in the laboratory through hardware prototyping. [ABSTRACT FROM PUBLISHER]

Published

2015

4. Single-Inductor Dual-Output DC–DC Converter With Capability of Feeding a Constant Power Load in Open-Loop Manner.

Author

Azadeh, Yalda, Babaei, Ebrahim, Tarzamni, Hadi, and Sabahi, Mehran

Subjects

ELECTRIC inductors, CONVERTERS (Electronics), ELECTRIC potential, DIODES, ELECTRIC switchgear

Abstract

In this paper, a single-inductor dual-output (SIDO) dc–dc converter is proposed. The significant feature of the proposed converter is feeding a constant power load in low-voltage side (LVS) port, where even feeding a variable load at LVS does not have any cross regulation to high-voltage side port with the desired approximation. Magnificently, both merits are obtained in open-loop manner, which is an outstanding characteristic in comparison with that of the existed converters. In this paper, soft commutation and soft switching of switches and diodes are investigated along with the aforementioned main novelty. Moreover, detailed theoretical analyses of the proposed SIDO dc–dc converter in continuous conduction mode are presented besides the comparisons with some other structures. Finally, theoretical analyses are verified through a 1500 W experimental prototype results. [ABSTRACT FROM AUTHOR]

Published

2019

5. Series-Capacitor-Based Buck PFC Converter With High Power Factor and Ultrahigh Step-Down Conversion Ratio.

Author

Chen, Zhangyong, Chen, Yong, Zhang, Chenyu, Wu, Yunfeng, and Zhang, Changhua

Subjects

CAPACITORS, CONVERTERS (Electronics), POWER factor measurement, ELECTRIC capacity, ELECTRIC potential

Abstract

In this paper, a series-capacitor-based interleaving buck power factor correction (PFC) converter is proposed, the intermediate energy storage capacitance of which is operated at discontinuous capacitor voltage mode (DCVM), and automatic power factor (PF) correction for this converter is obtained. Moreover, the voltage across the series capacitor of the proposed PFC converter is clamped at the input voltage, and thus peak voltage stress existed in the traditional DCVM buck PFC could be relieved. By effectively regulating the charge/discharge time for the series capacitor, ultrahigh step-down conversion ratio of the proposed converter is achieved, the conversion ratio of which is independent of the duty cycle and only related to the switching frequency and circuit parameters. Therefore, high PF can be obtained due to very narrow deadtime of the input current. Meanwhile, the proposed PFC converter can realize the soft turn-on of part power switch and soft turn-off of part power diodes. In addition, comparing with the traditional discontinuous inductor current mode PFC, the input current of the proposed PFC converter is continuous so that the peak value and root-mean-square value of input current can be reduced. The operational principle, performance analysis, and parameter design principle are given in this paper. The analysis results show that the PF and total harmonic distortion are also independent of the duty cycle. Finally, a 220-Vac input, 60 W/15 V output experimental prototype is built to verify the validity of the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

6. An Auxiliary-Capacitor-Based Active Phase Converter With Reduced Device Current Stress.

Author

Adapa, Anil K and John, Vinod

Subjects

CONVERTERS (Electronics), CAPACITORS, SEMICONDUCTOR devices, REACTIVE power, TOPOLOGY

Abstract

Reduced switch active phase converters (APC) are cost-effective solutions for running three-phase loads from single-phase grids. This paper proposes a novel auxiliary-capacitor-based APC (AC-APC) for this application. The combination of the topological location of the auxiliary capacitor and the control of the AC-APC reduces current stress on the semiconductor devices. In this paper, a selection criterion for the optimal auxiliary capacitor value is formulated to reduce the device currents in such a way that the overall efficiency is enhanced. This paper presents a comparative analysis of converter volt-ampere (VA) rating and device power loss for conventional H-bridge active front-end and inverter-based topology, APC, and AC-APC. To evaluate the efficacy of the proposed AC-APC, an experimental study is conducted on the APC and the AC-APC feeding a 3-hp three-phase induction motor. At a full load of $\text{2.5}\,\text{kW}$ and $\text{0.8 } \text{power factor}$ , the measured maximum efficiency of the AC-APC is $2\%$ higher than that of the APC. Analytical evaluation of converter currents and device power loss are in close agreement with experimental observations. [ABSTRACT FROM AUTHOR]

Published

2019

7. A Simple Approach to Enhance the Effectiveness of Passive Currents Balancing in an Interleaved Multiphase Bidirectional DC–DC Converter.

Author

Yao, Zhigang and Lu, Shuai

Subjects

DC-to-DC converters, CONVERTERS (Electronics), ZERO voltage switching, POWER density

Abstract

This paper studies the high power density bidirectional dc–dc converter with interleaving, soft-switching, and near critical conduction mode (near-CRM) operation. Systematic design and control methods are proposed to enhance the effectiveness of passive currents balancing between multiple interleaved phases without using individual phase current feedbacks. This paper first analyzes the zero voltage turn-on operation, including the turn-off energy diversion by the added snubber capacitor and the turn-off resonance models. Second, the intrinsic inverse co-relation between the phase current deviation and the resulting effective duty cycles variation is quantitatively formulated and modeled as a closed-loop mechanism that balances the currents passively. Then, the design constraints of the system parameters including the snubber capacitance, dead time, and valley currents of the near-CRM mode are formulated to guarantee the effectiveness of counteracting the current unbalance. Finally, a variable switching frequency control is proposed to actively control the valley current and maintain the current balancing effectiveness throughout the operating range. An IGBT-based 20-kW three-phase interleaved prototype with the maximum efficiency of 99.1% is constructed to verify the proposed design and control methods. [ABSTRACT FROM AUTHOR]

Published

2019

8. A New Pulse Generator With High Voltage Gain and Reduced Components.

Author

Khosravi, Reza and Rezanejad, Mohammad

Subjects

CAPACITOR switching, CONVERTERS (Electronics), SYNCHRONOUS capacitors, HIGH voltages, ELECTROMAGNETIC pulses, POWER supply circuits

Abstract

This paper proposes a new developed switched-capacitor converter to achieve high-voltage pulses with adjustable voltage level and frequency. The proposed topology generates repetitive high-voltage pulses by using low-voltage power supply with reduced number of components, including power semiconductors and capacitor. Therefore, a converter based on switched-capacitor units with high voltage gain and high efficiency can be achieved. Operation principles and design steps of the converter as well as comparative study with conventional converters are described in this paper. Finally, simulation and experimental results of a two-stage structure of the proposed circuit validate the operation principles and features of this topology. [ABSTRACT FROM AUTHOR]

Published

2019

9. A New Single DC Source Six-Level Flying Capacitor Based Converter With Wide Operating Range.

Author

Ebrahimi, Javad and Karshenas, Hamidreza

Subjects

DIRECT currents, CONVERTERS (Electronics), CAPACITORS, ELECTRIC power factor, HYBRID systems

Abstract

This paper presents a new six-level flying capacitor based (FC-based) multilevel converter with one dc source and the capability of operating in all power factors and modulation indexes. Multilevel converters with one dc voltage source are attractive in many applications as they do not need rather expensive and bulky multiwinding input transformer connection at the dc side. On the other hand, not all classic multilevel converters with one dc source can produce any desirable number of output voltage levels at all power factors and/or modulation indexes. In this paper, a hybrid structure is proposed in which six voltage levels can be realized at the ac terminals. The modulation technique and the control strategy for the FC voltage balancing are presented. To show the advantages of the proposed converter, different performance criteria, such as switch count and rating, the size of capacitors, switching frequency, and power losses, are compared with other existing six-level topologies. The results indicate that the proposed structure is superior to other six-level converters from different standpoints. Simulation results are used to further evaluate the performance of the proposed converter. A laboratory-type experimental setup is used to validate the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2019

10. Soft-Switched Nonisolated High Step-Down Converter.

Author

Cheshmdehmam, Dariush, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

CONVERTERS (Electronics), ZERO current switching, CAPACITORS, SEMICONDUCTOR devices, SEMICONDUCTOR diodes

Abstract

In this paper, a new nonisolated high step-down dc–dc converter with ultrahigh step-down conversion ratio is proposed. Advantages of the proposed converter are high step-down ratio, extended duty cycle, reduced switching losses by a converter operation under zero-voltage switching (ZVS) conditions, reduced reverse reco-very losses of diodes by achieved zero-current switching turn-off condition, and reduced voltage spikes by the inherent active-clamping structure of the converter. In this converter, series capacitors and coupled inductors have been used in power path to achieve the low voltage gain and extended duty cycle. By the inherent active-clamping structure of the proposed converter, the leakage inductance energy is totally recovered in the output; therefore, the high voltage spike across the semiconductor devices is suppressed. The switches of the proposed converter can operate under ZVS conditions, which cause reduced switching losses and improved efficiency. In this paper, the converter operating modes are discussed, and a prototype circuit is implemented. Experimental results are presented to verify the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

11. 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

12. 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

13. Optimal Design of −40-kV Long-Pulse Power Supply.

Author

Kim, S. C., Heo, H., Moon, C., Nam, S. H., Kim, D. S., Park, S. S., Kim, J. H., Oh, S. S., Yang, J. W., and Sho, J. H.

Subjects

CONSTANT-current power supply, SWITCHING power supplies, ELECTRON gun, CONVERTERS (Electronics), SURFACE charging

Abstract

This paper proposes a compact high-voltage pulse electron gun power supply (EGPS) consisted of interleaved capacitor-charging power supply (CCPS) with a series-resonant converter (SRC) to drive the electron tube. Requirement specifications are −40 kV, −7 A (280 kW), and continuous output lower than ±1% ripple stability lasted few seconds with <1 ms charging and discharging times. To meet the design specifications, eight stacks operate in parallel, and each stack has a 45° phase shift switching pulse width modulation (PWM) method. Each designed CCPS can supply −40-kV voltage and −0.9-A current. In addition, the proposed CCPS has the SRC to reduce the switching loss. The SRC is a famous topology, which presents main characteristics such as high-power density and efficiency. To prove the validity, this paper is confirmed by the simulation and experimental results of the fabricated −40-kV output CCPS with water load. Then, we implemented the fabricated EGPS to the electron tube. [ABSTRACT FROM PUBLISHER]

Published

2016

14. Single-Phase PFC Converter Using Switched Capacitor for High Voltage DC Applications.

Author

Kishore, G. Indira and Tripathi, Ramesh Kumar

Subjects

PERTURBATION theory, ELECTRIC power factor correction, SWITCHED capacitor circuits, CAPACITOR switching, CONVERTERS (Electronics)

Abstract

This paper presents a single-stage nonisolated switched capacitor ac–dc converter for power-factor correction (PFC). This converter features reduced passive components, single switch, transformerless high voltage gain, and improves the power factor, reduces total harmonic distortion, and voltage stress across the switch. The peak current mode with a dynamic resonant perturbation scheme compensates the subharmonics that exist at zero crossing of the source current is implemented for PFC. In this paper, the principle of operation, large signal modeling of the circuit, and control method for the proposed PFC converter are provided. [ABSTRACT FROM PUBLISHER]

Published

2018

15. High-Performance Switched-Capacitor Boost–Buck Integrated Power Converters.

Author

Allasasmeh, Younis and Gregori, Stefano

Subjects

CAPACITOR switching, CONVERTERS (Electronics), ENERGY conversion

Abstract

This paper presents the design of integrated boost and buck switched-capacitor power converters with high efficiency and fast start-up time. An analysis method is determined to evaluate the key performance parameters of integrated power converters, and techniques are proposed to improve the energy conversion efficiency and the dynamic response. Boost and buck structures are modeled and compared in static and transient conditions, including the losses due to parasitic elements. A switch bootstrapping technique prevents short-circuit losses, improves driving capability and start-up time, and enhances the overall efficiency. Moreover, the application of a charge-reuse technique reduces the dynamic power losses of the integrated structures. Prototypes of the integrated power converters were fabricated in a 180-nm CMOS process. Measurement results based on the proposed techniques are presented, demonstrating the improvements in steady-state and transient characteristics with a good correlation between measured and predicted results. [ABSTRACT FROM AUTHOR]

Published

2018

16. A High-Linearity Capacitance-to-Digital Converter Suppressing Charge Errors From Bottom-Plate Switches.

Author

Bing Li, Lei Sun, Chi-Tung Ko, Wong, Alex Kak-Yeung, and Kong-Pang Pun

Subjects

ELECTRIC capacity, CONVERTERS (Electronics), ELECTRIC power conversion, ELECTRIC switchgear, ELECTRIC appliance protection

Abstract

A high-precision capacitance-to-digital converter (CDC) that is configurable to interface with unipolar or push-pull-type capacitive sensors is presented in this paper. In the conventional switched-capacitor CDC, it is well known that clock feedthroughs and charge injections from top-plate switches can be eliminated by a bottom-plate sampling scheme. However, those charge errors from the bottom-plate switches depend on the digital output and the varying value of the sensing capacitor itself. They will thus affect the overall CDC linearity. When the varying range of the sensing capacitor is wide, the nonlinearity becomes more pronounced. This paper proposes new switching and calibration schemes to reduce these non-idealities. A prototype of a second order CDC employing the proposed techniques in a 0.18 μm CMOS process achieves a 53.2 aF RMS resolution with a 1 ms conversion time. The proposed calibration technique improves the linearity of the CDC from 9.3 bits to 12.3 bits and from 10.1 bits to 13.3 bits in the unipolar and push-pull-type sensing modes, respectively, with a sensing capacitance varying from 0.5 to 3.5 pF. The CDC is also demonstrated with a real-life pressure sensor. [ABSTRACT FROM AUTHOR]

Published

2014

17. An Isolated Three-Port Bidirectional DC–DC Converter for Photovoltaic Systems With Energy Storage.

Author

Zeng, Jianwu, Qiao, Wei, and Qu, Liyan

Subjects

DIRECT currents, CONVERTERS (Electronics), PHOTOVOLTAIC effect, PHOTOVOLTAIC cells, ENERGY storage

Abstract

This paper proposes a new isolated three-port bidirectional dc–dc converter for simultaneous power management of multiple energy sources. The proposed converter has the advantage of using the least number of switches and soft switching for the main switch, which is realized by using an inductor–capacitor–inductor ( $LCL$) -resonant circuit. The converter is capable of interfacing sources of different voltage–current characteristics with a load and/or a dc microgrid. The proposed converter is constructed for simultaneous power management of a photovoltaic (PV) panel, a rechargeable battery, and a load. Simulation and experimental results show that the proposed converter is capable of maximum power point tracking control for the PV panel, when there is solar radiation, and controlling the charge and discharge of the battery, when there is surplus energy and power deficiency with respect to the load, respectively. [ABSTRACT FROM PUBLISHER]

Published

2015

18. A Switched-Capacitor Three-Phase AC–AC Converter.

Author

Lazzarin, Telles B., Andersen, Romero L., and Barbi, Ivo

Subjects

SWITCHED capacitor circuits, CAPACITOR switching, CONVERTERS (Electronics), ELECTRIC power conversion, ENERGY conversion

Abstract

This paper proposes a bidirectional three-phase direct ac–ac converter, with only capacitors and switches in its power circuit and with its operation based on the switched-capacitor principle. The converter presents fixed gain, it keeps the frequencies of the output and input voltages equal, and it operates in open loop with constant switching frequency and duty cycle. The main advantages of the proposed converter are the absence of magnetic elements in the power circuit, the higher efficiency, the higher power density, the higher specific power, the lower cost, and the fact that it can convert ac–ac voltages within a wide frequency range, including dc voltage. Therefore, it is suitable to replace the conventional three-phase autotransformer in industrial, commercial, and residential applications, and it can be designated as a magnetic-less three-phase solid-state autotransformer. The principle of operation, a qualitative and quantitative analysis, the design methodology, and a fabricated example are described in this paper. In order to verify the converter in the laboratory, a prototype with the following characteristics was designed and fabricated: 6 kW, 1.35 kW/kg, 380/110 V, and switching frequency of 100 kHz. The measured efficiency at rated power was 96.3%, and other relevant experimental results are reported herein. [ABSTRACT FROM PUBLISHER]

Published

2015

19. Current-Ripple-Free Module Integrated Converter With More Precise Maximum Power Tracking Control for PV Energy Harvesting.

Author

Pan, Ching-Tsai, Cheng, Ming-Chieh, Lai, Ching-Ming, and Chen, Po-Yen

Subjects

PHOTOVOLTAIC power systems, MAXIMUM power point trackers, ENERGY harvesting, SWITCHING power supplies, CONVERTERS (Electronics), EQUIPMENT & supplies

Abstract

In this paper, a passive ripple canceling circuit (PRCC) is proposed to eliminate the output power reduction effect of photovoltaic (PV) systems caused by the current ripple of the PV converters. Special features of the proposed PRCC include having low-cost simple modular structure and being independent of the duty ratio control of the main power circuit. Hence, it can be easily integrated to the main power circuit to achieve zero input current ripple, yielding less filter size, loss, and fast response. Meanwhile, the linear line maximum power point tracking (MPPT) control is also integrated with the proposed module integrated converter (MIC) to achieve instantaneous tracking response. Finally, a 90-W laboratory prototype is constructed to verify the effectiveness of the proposed principle. It is seen that the resulting peak-to-peak input current ripple is reduced to about 2% of the original dc converter input ripple. In other words, the input current ripple is almost zero. As a result, the harvested power of the proposed MIC can be increased by 7% as compared with that of the MIC without the proposed PRCC. [ABSTRACT FROM AUTHOR]

Published

2015

20. Nonisolated Symmetrical Interleaved Multilevel Boost Converter With Reduction in Voltage Rating of Capacitors for High-Voltage Microgrid Applications.

Author

Bhaskar, Mahajan Sagar, Meraj, Mohammad, Iqbal, Atif, and Padmanaban, Sanjeevikumar

Subjects

VOLTAGE-frequency converters, CAPACITORS, VOLTAGE multipliers, SEMICONDUCTOR devices, CONVERTERS (Electronics), SEMICONDUCTOR diodes, ELECTRIC current rectifiers, HIGH voltages

Abstract

This article proposed a nonisolated symmetrical interleaved multilevel boost converter for high-voltage microgrid applications. The proposed converter configuration is derived from the integration of a voltage multiplier (VM) circuit with the front-end structure of the classical two-phase interleaved converter. Moreover, equal voltage rating capacitors and diodes are suitable to design multiple stages of the proposed converter. The proposed converter can feed from two independent sources or single source in the interleaved approach. The continuous input current, high-voltage gain, reduced voltage rating of capacitor (that causes reduction in cost), reduced components, and flexibility in number of sources make the proposed converter more attractive for renewable dc-microgrid applications such as, photovoltaic (PV) system, fuel cell (FC) system, and hybrid PV-FC system. Furthermore, the voltage gain of the converter can be increased by just adding similar stages of VM without preferring the high-voltage rating capacitors and without disturbing the front-end structure of the converter. Nonidealities are considered to analyze the proposed converter in a more practical way. The characteristics and operation of the proposed converter are discussed in this article with the continuous conduction mode and Discontinuous Conduction Mode boundary conditions. The design of the reactive components and selection of semiconductor devices are discussed. Additionally, the proposed converter is compared with recently proposed dc–dc multilevel converters. To support the proposed work, simulation and experimental results are provided which shows a good agreement with the analytical approach. [ABSTRACT FROM AUTHOR]

Published

2019

21. A Novel Transformerless Interleaved High Step-Down Conversion Ratio DC–DC Converter With Low Switch Voltage Stress.

Author

Pan, Ching-Tsai, Chuang, Chen-Feng, and Chu, Chia-Chi

Subjects

CONVERTERS (Electronics), CAPACITORS, ELECTRIC potential, VOLTAGE dividers, MOTHERBOARDS, BATTERY chargers

Abstract

In this paper, a novel transformerless interleaved high step-down conversion ratio dc–dc converter with low switch voltage stress is proposed. In the proposed converter, two input capacitors are series-charged by the input voltage and parallel-discharged by a new two-phase interleaved buck converter for providing a much higher step-down conversion ratio without adopting an extreme short duty cycle. Based on the capacitive voltage division, the main objectives of the new voltage-divider circuit in the converter are for both storing energy in the blocking capacitors for increasing the step-down conversion ratio and reducing voltage stresses of active switches. As a result, the proposed converter topology possesses the low switch voltage stress characteristic. This will allow one to choose lower voltage rating MOSFETs to reduce both switching and conduction losses, and the overall efficiency is consequently improved. Moreover, due to the charge balance of the blocking capacitor, the converter features automatic uniform current sharing characteristic of the interleaved phases without adding extra circuitry or complex control methods. The operation principles and relevant analysis of the proposed converter are presented in this paper. Finally, a 400-V input voltage, 25-V output voltage, and 400-W output power prototype circuit is implemented in the laboratory to verify the performance. [ABSTRACT FROM PUBLISHER]

Published

2014

22. An LLC Converter Family With Auxiliary Switch for Hold-Up Mode Operation.

Author

Wang, Hongliang, Chen, Yang, Fang, Peng, Liu, Yan-Fei, Afsharian, Jahangir, and Yang, Zhihua

Subjects

POWER electronics, ELECTRIC current rectifiers, PULSE width modulation, CAPACITORS, CONVERTERS (Electronics)

Abstract

This paper proposed a new half-bridge (HB) LLC resonant converter family with pulse-width modulated (PWM) auxiliary switch (sLLC converter) for hold-up mode operation. The proposed sLLC converters could operate with synchronous rectifier, which is suitable for low-output voltage applications. In the proposed converters, an auxiliary switch is added at the primary side to provide charging path for the series resonant inductor. For nominal 400-V input, sLLC achieves same performance as conventional LLC converter, and all the good features such as soft switching are naturally retained. For slight input voltage fluctuation, frequency modulation is used to regulate the output voltage. When the input voltage reduces further, HB switches will operate at constant minimum frequency, and the auxiliary switch will operate in the PWM mode to energize the resonant inductor with the bus voltage directly during hold-up period. Thus, the converter achieves higher voltage gain, and the output voltage can be maintained at desired level. To verify the effectiveness of the proposed sLLC converter, operational principle and equivalent circuits will be carefully explained and analyzed in this paper. A 300-W prototype is built for 250–400-V input 12-V output application. [ABSTRACT FROM AUTHOR]

Published

2017

23. A Wide Load Range ZVS Push–Pull DC/DC Converter With Active Clamped.

Author

Wu, Qunfang, Wang, Qin, Xu, Jialin, and Xiao, Lan

Subjects

CONVERTERS (Electronics), ZERO voltage switching, VOLTAGE spikes, ELECTRIC inductors, CAPACITORS

Abstract

A new active-clamped zero-voltage switching (ZVS) push–pull converter is proposed in this paper. Compared with the conventional push–pull converter, one auxiliary switch $Q_{{3}} and a clamping capacitor Ca are added in the primary side of the transformer to recycle the energy stored in the leakage inductors and clamp the voltage spike. Owing to the proposed converter which maintains ZVS of all the three switches from full load to very light-load condition, switching losses are reduced significantly. The voltage across the switch can be clamped at the input voltage plus the clamping capacitor voltage, i.e., V\rm{in}{+}VCa, are much less than those of a conventional push–pull converter that enabling the use of low-voltage, low-performance, and low-cost devices. In addition, the proposed topology can eliminate the problems of flux imbalance existing in the conventional one. Detailed operation, analysis, design, comparative study, and experimental results for the proposed converter are presented in this paper. An 800 W prototype was developed in the laboratory to evaluate and demonstrate the validity of the converter. [ABSTRACT FROM AUTHOR]

Published

2017

24. Integrated Control of Five-Level Diode-Clamped Rectifiers.

Author

Montero-Robina, Pablo, Salas, Francisco, Gordillo, Francisco, and Umbria, Francisco

Subjects

DIODES, ELECTRIC current rectifiers, CONVERTERS (Electronics), CAPACITORS, MODULATION theory

Abstract

This paper presents an approach for dealing with the control of five-level, diode-clamped rectifiers. The control of such converters is challenging, as voltage balancing among capacitors is not a trivial task. Some of the existing approaches that cope with this problem use specific modifications of one of the traditional modulation techniques, such as using redundant vectors in space vector modulation (SVM). The main feature of the proposed technique is that part of the modulation is considered in the system equations and, in this way, the voltage balance can be solved designing a specific controller for this problem. As a result, several levels are used within a switching period. Furthermore, it is shown that the proposed approach hardly affects the control of active and reactive powers and total dc-link voltage in such a way that the well-known direct power control can be applied. As a consequence, the resultant modulation stage is simpler than other techniques based on, e.g., SVM. The effectiveness and good performance of the system under the proposed control approach are validated by both simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

25. A Noninvasive Online Monitoring Method of Output Capacitor's C and ESR for DCM Flyback Converter.

Author

Yao, Kai, Li, Hui, Li, Lei, Guan, Chanbo, Li, Lingge, Zhang, Zhen, and Chen, Jienan

Subjects

CONVERTERS (Electronics), ELECTROLYTIC capacitors, CAPACITORS, AC DC transformers, DIGITAL signal processing, POWER electronics, LEAST squares, CASCADE converters

Abstract

In a power electronics system, an electrolytic capacitor (E-Cap) is widely used, whose performance degradation can be reflected by the change of capacitance (C) and equivalent series resistance (ESR). This paper proposes a new online C and ESR monitoring scheme for the output electrolytic capacitor in a discontinuous conduction mode (DCM) flyback converter. The mathematical relationship between the instantaneous capacitor voltage and other parameters is analyzed and then the scheme of undetermined coefficients based on the multiple-spot sampling and least square method is further proposed. In addition, considering the particularity of high ripple current and the resultant voltage ripple variation range, especially with the temperature, an inverse ripple voltage isolation amplifier with variable amplification factor and negative voltage elimination is put forward so as to make digital signal processor identify the temperature change easily. The proposed scheme is noninvasive as only voltage signals need to be sampled and no current sensor is necessary. A prototype is built and the experiments are made to verify the effectiveness of the proposed method, from which the data are in accordance with the results measured by an LCR meter. [ABSTRACT FROM AUTHOR]

Published

2019

26. A 1-MHz-Modified SEPIC With ZVS Characteristic and Low-Voltage Stress.

Author

Wang, Yijie, Gao, Shanshan, and Xu, Dianguo

Subjects

LOW voltage systems, ZERO voltage switching, CONVERTERS (Electronics), DIODES, CAPACITORS, ELECTRIC inductors

Abstract

A 1-MHz-modified single-ended primary-inductor converter (SEPIC) circuit is presented in this paper as an LED driver for automotive headlights. On the basis of traditional SEPIC, only a diode and two capacitors are added; therefore, the circuit structure is relatively simple and the volume is relatively small. High step-up capability is obtained with moderate duty cycle. Compared with traditional step-up circuit such as boost, low-voltage stress is gained which is beneficial to device selection. Zero-voltage switching is achieved at the same time to reduce switching loss. Planar inductors are used with the advantages of low profile and good thermal characteristic. Operational principle and parameters design process are introduced in detail. A 36-W prototype has been designed to demonstrate theoretical analysis. Obtained efficiency was up to 90.91% at full load. [ABSTRACT FROM AUTHOR]

Published

2019

27. Modular Multilevel Series/Parallel Converter With Switched-Inductor Energy Transfer Between Modules.

Author

F., Ricardo Lizana, Rivera, Sebastian, Li, Zhongxi, Luo, Jenny, Peterchev, Angel V., and Goetz, Stefan M.

Subjects

ENERGY transfer, BATTERY storage plants, CONVERTERS (Electronics)

Abstract

This paper presents a modular multilevel series/parallel converter (MMSPC) with intermodule switched-inductor power transfer. The switched-inductor voltage conversion feature allows controllable and efficient transfer of energy between modules with nonnegligible voltage difference, providing both step-down and step-up functionalities. Thus, this converter can accurately control and rapidly adjust the voltage of each module to generate an ac output voltage waveform with a controllable number of levels, increasing the quality of the output. Moreover, the intrinsic dc–dc conversion feature can generate a dc controllable output voltage and enable new applications. In this text, we specifically demonstrate how the flexibility of obtaining both ac and dc output with the same setup renders the topology promising for battery energy storage systems and dc microgrid applications. Experimental results validate the topology and concept of an MMSPC with intrinsic switched-inductor conversion. [ABSTRACT FROM AUTHOR]

Published

2019

28. A Novel Buck–Boost Converter With Low Electric Stress on Components.

Author

Li, Jing and Liu, Jinjun

Subjects

CONVERTERS (Electronics), VOLTAGE control, SIGNAL processing, ELECTRIC conductivity, CURRENT-mode circuits

Abstract

In this paper, a novel buck–boost converter with low electric stress on components and negative output voltage is proposed. The operational principle, steady-state analysis, and small-signal modeling of the proposed buck–boost converter in continuous conduction mode are presented. Comparisons among another five buck–boost converters and the proposed buck–boost converter are presented. It is found that the proposed converter's voltage gain is smaller than the other converters’ in step-down mode. Also, based upon the comparisons among the same kind and same number of components, the voltage and current stresses on the power switch of the proposed buck–boost converter are less than or equal to those of the comparative converters, and the voltage stress on the charge pump capacitor and the switching device power rating of the proposed buck–boost converter are always lower than those of other comparative converters. The efficiency of the proposed buck–boost converter is highest among those converters having the same number of elements. These advantages make component selection for the proposed converter much easier, and it can be used directly in applications needing a negative voltage source. Finally, simulation results and circuit experiments are given for validating the effectiveness of the proposed buck–boost converter. [ABSTRACT FROM AUTHOR]

Published

2019

29. A Five-Level Flying Capacitor Multilevel Converter With Integrated Auxiliary Power Supply and Start-Up.

Author

Stillwell, Andrew and Pilawa-Podgurski, Robert Carl Nikolai

Subjects

CAPACITORS, CONVERTERS (Electronics), POWER resources, LOW voltage systems, PHASE shifters

Abstract

This paper presents a five-level flying capacitor multilevel (FCML) converter with an integrated auxiliary power converter to supply power to the controller and gate drive circuitry. The auxiliary power converter is sourced from within the FCML converter at a naturally occurring low-voltage node, reducing the voltage rating requirements by 75% and thus the size of the auxiliary converter. The auxiliary load current drawn from the FCML converter induces an imbalance in the flying capacitors, which is detrimental to the capacitor and switch ratings if left unchecked. To compensate for this imbalance, an active-balancing method is proposed that adjusts the phase and duty cycle of the traditional phase-shifted pulsewidth modulated control signals. The active balancing requires only a single capacitor voltage measurement and proportional control with no additional hardware components. A start-up circuit is proposed to power the auxiliary power supply and soft-start the FCML converter. Experimental results have been demonstrated with an experimental prototype resulting in an excellent flying capacitor balancing and FCML start-up. [ABSTRACT FROM AUTHOR]

Published

2019

30. 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

31. Analysis and Design of a Single-Stage Bridgeless High-Frequency Resonant AC/AC Converter.

Author

He, Qingqing, Luo, Quanming, Ma, Kun, Sun, Pengju, and Zhou, Luowei

Subjects

CONVERTERS (Electronics), RESONANT states, ALTERNATING currents, ELECTRIC currents, ELECTRIC current rectifiers

Abstract

A single-stage high-frequency resonant ac/ac converter converts the ac-line input voltage into the high-frequency sinusoidal output voltage, which consists of two power conversion units, i.e., a power factor correction (PFC) unit and a high-frequency resonant dc/ac unit, and it can be used to derive a modular multichannel constant current LED driver. By adopting a totem-pole bridgeless PFC boost rectifier to reduce conduction losses, a single-stage bridgeless high-frequency resonant ac/ac converter is proposed in this paper. The operating principle is described, and the performance analysis is presented in detail. Moreover, the quantitative parameter design method of the main circuit is presented, which is suitable for other single-stage ac input converters, such as a single-stage PFC rectifier. Finally, a 130-W prototype has been built and tested to verify the correction of related theoretical analysis and parameter design. [ABSTRACT FROM AUTHOR]

Published

2019

32. Optimized Design of the Neutral Inductor and Filter Inductors in Three-Phase Four-Wire Inverter With Split DC-Link Capacitors.

Author

Lin, Zhiheng, Ruan, Xinbo, Jia, Lei, Zhao, Wenxin, Liu, Haitao, and Rao, Peinan

Subjects

CAPACITORS, ELECTRIC inductors, CONVERTERS (Electronics), ELECTRIC potential, ELECTRIC circuits

Abstract

The three-phase four-wire inverter with split dc-link capacitors can supply unbalanced loads. For the purpose of reducing the filter inductors, a neutral inductor could be introduced into the neutral line. This paper analyzes the operation principle of the three-phase four-wire inverter with split dc-link capacitors when a neutral inductor is introduced. It is illustrated that the neutral inductor can reduce the zero-sequence switching harmonics in the voltages between the phase-leg midpoints and the output neutral point, thus the filter inductors can be reduced. The optimized design of the neutral inductor and filter inductors is proposed with the considerations of the inductor current ripple, the ability of supplying unbalanced loads, and the total energy stored in the inductors. The equivalent circuits of the three-phase four-wire inverter with split dc-link capacitors and neutral inductor is derived in the α–β–0 frame, and the zero-axis voltage regulator is modified to suppress the third-order harmonic in the zero-sequence current caused by the deadtime of the drive signals for the power switches. Finally, the experimental results from a 9-kW prototype are provided to prove the effectiveness of the proposed optimized design of the neutral inductor and filter inductors and the control strategy of the inverter. [ABSTRACT FROM AUTHOR]

Published

2019

33. Analysis and Design of the Integrated Double Buck–Boost Converter as a High-Power-Factor Driver for Power-LED Lamps.

Author

Alonso, J. Marcos, Vina, Juan, Vaquero, David Gacio, Martinez, Gilberto, and Osorio, René

Subjects

CONVERTERS (Electronics), ELECTRIC power, LIGHT emitting diodes, LAMPS, ELECTRIC inductors, CAPACITORS, ELECTRIC power factor, ELECTRIC inductance

Abstract

In this paper, an integrated double buck–boost (IDBB) converter is proposed as a high-power-factor offline power supply for power-LED lamps. The IDBB converter features just one controlled switch and two inductors and is able to supply a solid-state lamp from the mains, providing high power factor and good efficiency. In this paper, the IDBB converter is analyzed, and a design methodology is proposed. It is demonstrated that, with a careful design of the converter, the filter capacitances can be made small enough so that film capacitors may be used. In this way, the converter mean time between failures can be made as high as that of the solid-state lamp. A design example for a 70-W converter supplied from a 230 V/50 Hz mains for street lighting applications is shown. Finally, experimental results from a laboratory prototype are also presented. [ABSTRACT FROM AUTHOR]

Published

2011

34. High Step-Up Quasi-Z Source DC–DC Converter.

Author

Haji-Esmaeili, Mohammad Mehdi, Babaei, Ebrahim, and Sabahi, Mehran

Subjects

CONVERTERS (Electronics), DIRECT currents, ELECTRIC inductors, CASCADE converters, CAPACITORS

Abstract

In this paper, a high step-up quasi-Z Source (QZS) dc–dc converter is proposed. This converter uses a hybrid switched-capacitors switched-inductor method in order to achieve high voltage gains. The proposed converter have resolved the voltage gain limitation of the basic QZS dc–dc converter while keeping its main advantages, such as continuous input current and low voltage stress on capacitors. Compared to the basic converter, the duty cycle is not limited, and the voltage stress on the diodes and switch is not increased. In addition to these features, the proposed converter has a flexible structure, and extra stages could be added to it in order to achieve even higher voltage gains without increasing the voltage stress on devices or limiting the duty cycle. The operation principle of the converter and related relationships and waveforms are presented in the paper. Also, a comprehensive comparison between the proposed and other QZS based dc–dc converters is provided which confirms the superiority of the proposed converter. Simulations are done in power systems computer aided design (PSCAD) in order to investigate the maximum power point tracking (MPPT) capability of the converter. In addition, the valid performance and practicality of the converter are studied through the results obtained from the laboratory built prototype. [ABSTRACT FROM AUTHOR]

Published

2018

35. A 0.016 mV/mA Cross-Regulation 5-Output SIMO DC–DC Buck Converter Using Output-Voltage-Aware Charge Control Scheme.

Author

Pham, Ngoc-Son, Yoo, Taegeun, Kim, Tony Tae-Hyoung, Lee, Chan-Gun, and Baek, Kwang-Hyun

Subjects

DIRECT currents, COMPUTER systems, TOTAL energy systems (On-site electric power production), CONVERTERS (Electronics), ELECTRICAL engineering

Abstract

A single-inductor multiple-output (SIMO) dc–dc converter with output-voltage-aware charge control (OVACC) is presented in this paper. The OVACC scheme reduces the cross regulation by computing the total energy required by all outputs to extract exactly the same amount of energy from the input. Moreover, the proposed design also extends the load capability range of the SIMO converter by supporting the operation in both continuous conduction mode and discontinuous conduction mode while boosting the overall power efficiency. The proposed SIMO (five outputs) dc–dc converter has been implemented in a 0.18 μm 1P6M CMOS process. Measurement results show that the best cross regulation is 0.016 mV/mA when the output current of 250 mA abruptly changes. And no cross regulation is observed when the first output current changes 150 mA, the second output current changes 160 mA, the third and fourth output currents change 180 mA, and the last output current changes 250 mA. Also, the measured peak power efficiency is 86%. [ABSTRACT FROM AUTHOR]

Published

2018

36. A Compact MMC Submodule Structure With Reduced Capacitor Size Using the Stacked Switched Capacitor Architecture.

Author

Tang, Yuan, Chen, Minjie, and Ran, Li

Subjects

OFFSHORE wind power plants, CONVERTERS (Electronics), CAPACITOR switching, ELECTRIC potential, ENERGY dissipation, ELECTRIC power distribution grids

Abstract

Modular multilevel converters (MMCs) are being developed for the grid connection of offshore wind or tidal farms. In order to reduce the construction and maintenance costs, it is desirable to reduce the weight and volume of the system. In current MMC submodule designs, the reservoir capacitor usually accounts for over 50% of the total volume and 80% of weight. This paper presents a new design concept and control principle for a submodule using the stacked switched capacitor (SSC) architecture that can significantly reduce the capacitor size in an MMC. Practical considerations for a high-voltage high-power SSC-based MMC submodule are presented in this paper, through the design of a 21-level, 40-kV (pole-pole dc), 19.1-MW, grid-connected system, and the concept is demonstrated experimenttally on a scaled-down 400-V, 12.3-Apeak laboratory prototype submodule. It is shown that with the proposed SSC architecture, the total volume of capacitors in each submodule can be reduced by more than 40% without significantly increasing the power loss. [ABSTRACT FROM AUTHOR]

Published

2016

37. Comparison of a Buck Converter and a Series Capacitor Buck Converter for High-Frequency, High-Conversion-Ratio Voltage Regulators.

Author

Shenoy, Pradeep S., Amaro, Michael, Morroni, Jeff, and Freeman, Dave

Subjects

VOLTAGE regulators, CONVERTERS (Electronics), ENERGY transfer, ENERGY dissipation, SWITCHING circuits, COMPARATIVE studies

Abstract

This paper presents an analytical and experimental comparison of a two-phase buck converter and a two-phase, series capacitor buck converter. The limitations of a conventional buck converter in high-current (10 A or more), and high-frequency (HF, 3–30 MHz) point-of-load voltage regulators with large voltage conversion ratios (10-to-1) are highlighted. The series capacitor buck converter exhibits desirable characteristics at HF, including lower switching loss, less inductor current ripple, automatic phase current balancing, duty ratio extension, and soft charging of the energy transfer capacitor. Analysis of the topologies indicates that switching loss and inductor core loss can dominate at HF. Results from side-by-side 12 V input, 1.2 V output hardware prototypes demonstrate that the series capacitor buck converter has up to 12 percentage points higher efficiency at 3 MHz and reduces power loss by up to 33% at full load (10 A). Some guidelines for inductor selection are provided, and a switch stress comparison reveals that the maximum converter switch stress is reduced by 30%. [ABSTRACT FROM AUTHOR]

Published

2016

38. Heuristic Model Predictive Modulation for High-Power Cascaded Multilevel Converters.

Author

Townsend, Christopher D., Baraciarte, Roberto A., Yu, Yifan, Tormo, Daniel, de La Parra, Hector Zelaya, Demetriades, Georgios D., and Agelidis, Vassilios G.

Subjects

ELECTRONIC modulation, CONVERTERS (Electronics), PHASE shifters, ELECTRIC potential, SEMICONDUCTOR research

Abstract

Phase-shifted carrier modulation is an industry standard in its application to multilevel H-bridge converters. The major advantage of this scheme over level-shifted and space vector modulation schemes is its inherent ability to evenly distribute losses between semiconductor devices. However, phase-shifted schemes suffer from harmonic degradation when operated at the low carrier frequencies required in high-power high-level number applications. This paper develops a model predictive modulation (MPM) scheme that achieves superior harmonic performance, compared to phase-shifted modulation, while ensuring equal semiconductor loss distribution. With respect to complete-enumeration-based predictive techniques, the proposed modulation significantly reduces the number of times the system cost function is evaluated. Reducing the number of calculations by several orders of magnitude ensures computational feasibility. Simulation and experimental results are presented, which confirm correct operation of the modulation strategy. [ABSTRACT FROM PUBLISHER]

Published

2016

39. Minimum Flying Capacitor for N-Level Capacitor DC/DC Boost Converter.

Author

Ponniran, Asmarashid Bin, Orikawa, Koji, and Itoh, Junichi

Subjects

CAPACITORS, CONVERTERS (Electronics), ELECTRIC capacity, ELECTRIC inductors, CIRCUIT elements

Abstract

This paper proposes a multilevel flying capacitor dc/dc boost converter (FCBC) with a small capacitance of the flying capacitor for the reduction of converter size. In this paper, the design methods for the boost inductor and the flying capacitor in the n-level FCBC are principally and experimentally confirmed. Furthermore, the boost inductor is designed based on maximum product of voltage-time, regardless the number of level. Meanwhile, the minimum capacitance of the flying capacitor is designed based on the maximum switching device voltage stress, regardless of the output voltage ripple influences. Moreover, the achieved maximum efficiency of the designed three-level FCBC is 98.5% at the output power of 1 kW. Finally, the effectiveness of small capacitances of the flying capacitor in the three-level and five-level FCBCs is analyzed. The characteristics of the distorted voltage across the input voltage source and the boost inductor, and the distorted current to the output side (output capacitor and load) are investigated with several capacitances of the flying capacitors in the three-level and five-level FCBCs. As a result, it is experimentally confirmed that the distorted voltage is drastically reduced by increasing the number of level. Besides, the distorted current is almost the same although the number of level is increased. Therefore, based on the experimental results, it is shown that small capacitance of the flying capacitor can be used in the n-level FCBC without compromising the stability of converter operation. [ABSTRACT FROM PUBLISHER]

Published

2016

40. A Novel SVPWM Algorithm for Five-Level Active Neutral-Point-Clamped Converter.

Author

Liu, Zhan, Wang, Yu, Tan, Guojun, Li, Hao, and Zhang, Yunfeng

Subjects

CONVERTERS (Electronics), COORDINATE transformations, ENERGY conversion, HIGH voltages, CAPACITORS

Abstract

The five-level active neutral-point-clamped (5L-ANPC) converter is becoming an attractive topology of multilevel converter family. A novel SVPWM algorithm based on line voltage coordinate was studied in this paper to overcome shortcomings of the traditional algorithm. Through coordinate transformation, steps of determining the basic vectors and the solution about the basic vector corresponding action time are simplified. Combining with the characteristics of 5L-ANPC converter and the new control algorithm, a method of controlling the voltage balancing of dc-link capacitors and floating-capacitors is proposed. According to the voltage of dc-link capacitors, the suitable switching sequence which can balance the voltage of dc-link capacitors is chosen. The high common-mode voltage will affect the service life of motor and reduce the reliability of the system especially in high-voltage converter. The common-mode voltage is also reduced by choosing the right switching state in this paper. The validity of the proposed method was proved by the experimental results. [ABSTRACT FROM AUTHOR]

Published

2016

41. Three-Phase Series-Connected Modular Multilevel Converter for HVDC Application.

Author

Hao, Quanrui, Ooi, Boon-Teck, Gao, Feng, Wang, Can, and Li, Nan

Subjects

CONVERTERS (Electronics), HIGH-voltage direct current transmission, SEMICONDUCTOR switches, PULSE width modulation, OVERCURRENT protection, CURRENT limiters

Abstract

The three-phase series-connected modular multilevel converter (SC-MMC) is presented as one option for high-voltage direct current (HVDC) tap to reduce the cost of an HVDC station. Compared with conventional three-phase parallel-connected MMC, the number of semiconductor switches in SC-MMC is reduced by one-third to withstand the same dc voltage. First, the paper studies the operating principle of SC-MMC, and then presents an interspacing phase-shifted pulsewidth-modulated method which could improve the waveform of the output ac voltage for a given switching frequency. Next, the control strategy based on the identical real power input of each phase is proposed to balance the dc voltage of each phase under an unbalanced grid condition. The current limit of switching devices is also taken into consideration to protect SC-MMC from overcurrent. Furthermore, a universal zero-sequence current controller is developed as one part of the control strategy. In addition, an innovative method to suppress the third harmonics of ac current is presented. With the third harmonic suppression strategy, the SC-MMC can operate with much smaller SM capacitors without deteriorating the ac current, which contributes to the cost reduction further. Finally, simulation results obtained in PSCAD/EMTDC are provided to validate the proposed control strategies. [ABSTRACT FROM PUBLISHER]

Published

2016

42. Switching Frequency Analysis of Staircase-Modulated Modular Multilevel Converters and Equivalent PWM Techniques.

Author

Konstantinou, Georgios, Pou, Josep, Ceballos, Salvador, Darus, Rosheila, and Agelidis, Vassilios G.

Subjects

CONVERTERS (Electronics), ELECTRIC potential, SWITCHING theory, PULSE width modulation, ELECTRICAL harmonics

Abstract

The large number of voltage levels in a modular multilevel converter (MMC) make staircase modulation a feasible alternative, particularly in high-power applications. However, staircase waveforms do not necessarily mean operation of the MMC submodules (SMs) at the fundamental frequency. This paper presents an analysis of SM switching frequencies in staircase-modulated MMCs and their correlation to the modulation index and load phase angle. A carrier-based pulsewidth-modulation (CB-PWM) equivalent technique is also developed. This analysis demonstrates that CB-PWM techniques provide a similar switching frequency with superior harmonic performance and improved voltage balancing characteristics at all modulation indices compared to staircase modulation. The theoretical analysis is verified with extensive simulation results for MMCs with different SMs and experimental results from a laboratory prototype. [ABSTRACT FROM PUBLISHER]

Published

2016

43. New Multilevel Converter Based on Cascade Connection of Double Flying Capacitor Multicell Converters and Its Improved Modulation Technique.

Author

Sadigh, Arash Khoshkbar, Dargahi, Vahid, and Corzine, Keith A.

Subjects

CONVERTERS (Electronics), CAPACITORS, ELECTRONIC modulation, INSULATED gate bipolar transistors, MATHEMATICAL models

Abstract

This paper proposes a new multilevel converter based on the cascade connection of double flying capacitor multicell (DFCM) converters, as multilevel modules, to decrease the voltage diversity of the flying capacitors. Furthermore, a new switching pattern based on the phase-shifted pulse-width modulation technique is proposed to reduce the voltage ripple across the flying capacitors. Moreover, the proposed modulation technique reduces the rms value of the current flowing through flying capacitors. This results in an increase in the life time of flying capacitors and a decrease in the capacitance of the flying capacitors, to keep the same amount of the ripple, meaning a reduction in the physical size of the converter. In addition, this paper presents an analytical approach to calculate the average and rms currents of the insulated gate bipolar transistors (IGBTs)/diodes in the DFCM converter in a closed-form expression. The derived closed-form equations to calculate the average and rms currents of the IGBTs/diodes are utilized to investigate the conduction power losses in a DFCM converter and the proposed multilevel converter. Numerical results of the derived closed-form equations match the simulation results well, which validates the derived equations. Furthermore, simulation results and experimental measurements of the proposed multilevel power converter, configured by cascading two two-cell five-level DFCM converters, are presented to validate the performance of the proposed converter as well as the suggested modulation technique. [ABSTRACT FROM AUTHOR]

Published

2015

44. Dynamic Modeling and Analysis of Constant On Time Variable Frequency One-Cycle Control for Switched-Capacitor Converters.

Author

Yang, Lei, Wu, Bin, Zhang, Xiaobin, Smedley, Keyue, and Li, Guann-Pyng

Subjects

CAPACITORS, CAPACITOR switching, CONVERTERS (Electronics)

Abstract

A constant on time variable frequency one-cycle control technique (CVFOCC) for switched-capacitor (SC) converters is presented in this paper. It is designed to accomplish the continuous variable conversion ratio and fast dynamical response to reject the external disturbance. A proper regulation can be obtained by controlling the related “off time” of a transistor with the constant “on time” which is less than the time constant $\tau $ of the charge loop. A unique large-signal dynamic capacitor ampere-second balance (CASB) model for SC converters is applied in this research study. It is implemented to instantaneously estimate transient values of the equivalent circuits. The proposed modeling method and analysis have been verified by comparing the modeling expressions with simulation and experiment results for different input voltages, load currents and switching frequencies. The simulation and experiment results show that the external disturbance of a single-stage SC converter could be immediately rejected by the proposed control method. The good line and load regulation are demonstrated. The proposed control method is stable and global. It can work in a wide operation range with a simple control circuit for general SC converters. [ABSTRACT FROM AUTHOR]

Published

2017

45. Offline Soft-Switched LED Driver Based on an Integrated Bridgeless Boost–Asymmetrical Half-Bridge Converter.

Author

Almeida, Pedro S., Braga, Henrique A. C., Dalla Costa, Marco A., and Alonso, J. Marcos

Subjects

LIGHT emitting diodes, ELECTRIC switchgear, ELECTRIC power factor, CONVERTERS (Electronics), ELECTRIC capacity, ELECTROLYTIC capacitors

Abstract

This paper proposes an offline single-stage light-emitting diode (LED) driver based on a novel approach to reduce low-frequency ripple in LED arrays supplied from mains, while assuring high input power factor (PF). The proposal employs a series resonant dc–dc converter integrated into a bridgeless boost power factor correction (PFC) stage. The resonant stage works to reduce the low-frequency ripple transmitted from the output of the PFC stage to the LEDs with only small power losses. This solution achieves three main goals: 1) reduction of the bulk capacitance used at the dc bus, allowing for the use of long-life film capacitors; 2) increase in the overall efficiency of the LED driver owing to the low switching and conduction losses in the shared switching network; and 3) assuring high input PF. Experimental results of a driver without electrolytic capacitors for a 100-W street lighting LED luminaire are presented, showing overall efficiency in excess of 92%, input PF greater than 0.97, and line current harmonic content in compliance with the IEC 61000-3-2 standard. [ABSTRACT FROM AUTHOR]

Published

2015

46. Natural Balancing of the 2-Cell Modular Multilevel Converter.

Author

van der Merwe, Wim

Subjects

SINGLE-phase alternating currents, MULTILEVEL models, CONVERTERS (Electronics), HARMONIC analysis (Mathematics), FREQUENCY-domain analysis, FOURIER series

Abstract

Natural balancing of the cell voltages is observed in many multilevel converters, however, this was not previously described for the modular multilevel converter (MMC). This paper introduces a method whereby the self-balancing behavior of the MMC can be described and analyzed. A novel equivalent circuit of the two cell single phase MMC is introduced whereby the unbalance in the system is clearly stated. Using this equivalent circuit a method, using the frequency domain as basis for analysis, is proposed whereby the self-balancing properties of the converter can be described. The method is verified through comparison with simulation results. [ABSTRACT FROM AUTHOR]

Published

2014

47. Voltage Balancing and Commutation Suppression in Symmetrical Cascade Multilevel Converters for Power Quality Applications.

Author

de Alvarenga, Marcos Balduino and Pomilio, Jose Antenor

Subjects

CASCADED counters, CONVERTERS (Electronics), DIRECT currents, COMMUTATION (Electricity), VOLTAGE regulators

Abstract

This paper presents a modulation strategy for symmetrical cascaded multilevel converters that simultaneously balances the individual DC voltages and reduces switching losses by eliminating redundant or unnecessary commutations. The voltage regulation is based on a 1-bit digital signal indicating whether the DC link voltage of each H-bridge is above or below the set point. The system command identifies commutations that can be suppressed without causing output voltage distortion, thus reducing converter losses. The voltage balancing is reached by postponing each switching commutation for a short lapse of time. Simulation and experimental results for an active filter application validate the proposed methods. [ABSTRACT FROM PUBLISHER]

Published

2014

48. Study of Subharmonic Oscillation Mechanism and Effect of Circuit Propagation Delay for Buck Converters With Constant On-Time Control.

Author

Qian, Ting

Subjects

SUBHARMONIC functions, OSCILLATIONS, ELECTRIC circuits, CONVERTERS (Electronics), ELECTRIC power

Abstract

This paper explores the subharmonic oscillation mechanism for constant on-time control, which has been widely used for power supply controllers in industry. As well as analyzing the stability criterion, this research reveals that the circuit propagation delay (\Delta t) can significantly increase the demand of ESR\cdot Co value for stable operation in practical applications. A thorough study is provided based on the inductor current information and the charge variations of the output capacitor. Thus, critical condition for subharmonic oscillation is derived, and the effect of circuit propagation delay is also quantified. Based on detailed analysis, a prototype with constant on-time control and added inductor current ramp is built. Experimental results verify the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2013

49. Dynamic Capacitor Ampere-Second Balance Transient Calculation Modeling Method for Switched-Capacitor Converters.

Author

Yang, Lei, Wu, Bin, Tong, Xiangqian, Smedley, Keyue Ma, and Li, Guann-Pyng

Subjects

CAPACITORS, CIRCUIT elements, CAPACITOR switching, CONVERTERS (Electronics), ELECTRIC power conversion

Abstract

Switched-capacitor (SC) converters have drawn more and more attention in recent years due to their unique advantages. The accurate analysis methods will fully determine an SC converter's steady-state and dynamical performance. Proper design of SC converters requires full understanding of all impacts on circuit operation including steady-state and dynamical performance. Some previous modeling methods for SC converters have established a popular static model for SC converters which is composed of an ideal transformer and equivalent output resistance. This paper presents a dynamic capacitor ampere-second balance transient calculation modeling method. The instantaneous state of input voltage, instantaneous state of output voltage, instantaneous state of voltage of flying capacitor, “on time” and “off time,” as well as switching period are all included in the proposed model. The proposed modeling method was applied in both the dual-phase SC converters and the two-switch boosting SC converters. This modeling method was validated by the simulation and experimental results. The proposed model can be used to accurately predict and optimize the performance in the design phase for the low and high power SC converters. Based on the proposed modeling method, the SC converters could be controlled by a variable frequency control method. [ABSTRACT FROM AUTHOR]

Published

2018

50. Nonisolated Harmonics-Boosted Resonant DC/DC Converter With High-Step-Up Gain.

Author

Huang, Ying, Xiong, Song, Tan, Siew-Chong, and Hui, Shu Yuen

Subjects

ELECTRICAL harmonics, CONVERTERS (Electronics), RENEWABLE energy sources, DIRECT currents, CAPACITORS, ENERGY consumption

Abstract

High-step-up dc/dc converters are widely required in grid-connected applications with renewable energy sources. An extremely high-ratio step-up nonisolated dc/dc converter, in the form of a harmonics-boosted resonant converter, is proposed in this paper. This proposed converter consists of a high-frequency dc/ac inverter stage that is followed by a passive ac/dc rectifier stage connected in cascade. Conventionally, such a dc/ac inverter is designed to output a pure sinusoidal ac voltage with an amplitude several times the amplitude of the input voltage. However, for the proposed converter, the harmonics-boosted inverter stage is designed to contain selected voltage harmonics that significantly boost the amplitude of its output voltage. This greatly increases the overall gain of the converter. The adopted ac/dc stage is a diode-capacitor rectifier, which is of high efficiency and easily extendable to increase the voltage gain. Importantly, the proposed converter involves only one active switch. With only one active switch, the driver's loss is minimized and the converter's control is simplified. Zero-voltage switching is applied to reduce the switching loss, which also allows the converter to operate efficiently at high frequency, and thus can be designed for high power density. The optimal design of the two converter stages and their combined voltage gain is investigated and reported. Besides, a design guideline of the proposed converter is provided. A prototype of a 57-time harmonics-boosted resonant converter with 3.3 V input voltage, 500 kHz switching frequency, and 21 W output power, is built. The experimental result shows that the achieved converter's efficiency is as high as 88.6%. [ABSTRACT FROM AUTHOR]

Published

2018