Showing total 20 results

1. High-Power Thyristor-Based DC–DC Switched-Capacitor Voltage Multipliers: Basic Concept and Novel Derived Topology With Reduced Number of Switches.

Author

Kawa, Adam, Stala, Robert, Mondzik, Andrzej, Pirog, Stanislaw, and Penczek, Adam

Subjects

*SWITCHED capacitor circuits, *THYRISTORS, *DC-to-DC converters, *VOLTAGE multipliers, *POWER electronics, *COMPUTER simulation, *ENERGY consumption

Abstract

This paper presents concepts and results of an investigation of power electronic thyristor-based switched-capacitor voltage multipliers (SCVMs). A concept of the SCVM power converters assumes the utilization of resonant circuits for the zero-current switching operation. The topology makes it possible to apply thyristors as active switches that create the possibility of composing the resonant switch-mode converters for high-voltage gain, high power, and low cost, and opens a huge area of applications. This paper presents an in-depth analysis of the SCVM configured as the resonant high-power thyristor-based converter. The operation with regard to the specific switching conditions of thyristors, as well as efficiency of the converter is analyzed providing the unique relationship important for the converter design, optimization, and efficiency improvement. An experimental validation confirms the feasibility and the operation concept of the SCVM and demonstrates the efficiency range. The SCVM converter can be optimized to the topology with a decreased number of switches. This paper also presents a novel topology of the resonant converter with a reduced number of switches, resonant switched capacitor voltage multiplier (RSCVM), dedicated for thyristor implementation. The RSCVM requires the specific component selection and control. The analysis of the configuration, operation, efficiency, and component selection of the RSCVM converter, as well as simulation and experimental results are presented. [ABSTRACT FROM AUTHOR]

Published

2016

2. A New Resonant Modular Multilevel Step-Down DC–DC Converter with Inherent-Balancing.

Author

Xiaotian Zhang, Green, Timothy C., and Junyent-Ferre, Adria

Subjects

*RESONANT power convertors, *DC-to-DC converters, *HIGH voltages, *ELECTRIC transformers, *POWER electronics, *ELECTRIC power conversion

Abstract

Modular multilevel converters (MMCs) have become increasingly interesting in dc-dc applications, as there is a growing demand for dc-dc converters in high-voltage applications. Power electronics transformers can be used for high step-down ratio dc-dc power conversion, with high power rating and efficiency achieved. However, this arrangement requires a large number of high isolation voltage transformers and a complicated balancing control scheme. To provide a simple solution with inherent voltage balancing, this paper presents a new resonant MMC topology for dc-dc conversion. The proposed converter achieves high-voltage step-down ratio depending on the number of submodules. The converter also exhibits simplicity and scalability with no necessary requirement of high-voltage isolation transformers. By using phase-shift control, a much higher converter operating frequency is achieved compared to the switching frequency. Resonant conversion is achieved between the series inductor and submodule capacitors. The operation principle and theoretical analysis are presented in this paper, which have been verified by experimental results based on a bench-scale prototype. [ABSTRACT FROM AUTHOR]

Published

2015

3. Design and Implementation of a Transformerless Single-Stage Single-Switch Double-Buck Converter With Low DC-link Voltage, High Step-Down, and Constant Input Power Factor Features.

Author

Yu Chen, Zhihao Zhong, and Yong Kang

Subjects

*ELECTRONIC switch-mode DC-to-DC converters, *ELECTRIC transformers, *VOLTAGE-frequency converters, *ELECTRIC power factor, *DC-to-DC converters

Abstract

This paper presents a new transformerless single-stage single-switch (S4) converter which integrates a buck-type power factor correction cell with a buck-type dc-dc output cell in a special way. The proposed converter preserves the advantages of existing transformerless S4 converters, such as the low voltage stress across the dc-link capacitor, low current stress of the switch, and high step-down input-to-output voltage. Moreover, the proposed converter provides a new attractive feature, i.e., its input power factor always keeps constant even when the line- and load-conditions vary. These characteristics make the proposed converter cost-efficient, easy-to-design, and suitable for the low-power and nonisolated applications. The principle and analysis of the proposed converter are presented in this paper, and a design example is also given to show the validity of analysis. [ABSTRACT FROM AUTHOR]

Published

2014

4. A Modular Multilevel DC–DC Converter Topology With a Wide Range of Output Voltage.

Author

Ren, Qiang, Sun, Chi, and Xiao, Fei

Subjects

*ELECTRIC potential, *DC-to-DC converters, *ELECTRIC current converters, *POWER capacitors, *CLOSED loop systems

Abstract

To solve some problems caused by the ac control method used for the existing modular multilevel dc–dc converter (MMDC), this paper has proposed a new MMDC topology with a wide range of output voltage by means of dc control. By reconstructing the submodule structure, the converter has a power branch and an auxiliary balance branch, which are used to transmit dc power and balance the capacitor voltage, respectively. Both dc analysis and control method are adopted to establish a mathematical model so as to deduce the mathematical relationships between the key electrical parameters. Moreover, what have been done include analyzing the self-balancing principle of the capacitor voltage and the mechanism of the auxiliary balance branch, calculating the related parameters of the capacitor voltage fluctuation, and presenting a dc closed-loop control strategy based on a small-signal model. The analyses of the steady and dynamic states in combination with simulation and experiment show that the proposed converter can stably operate in the mode of dc control, with a large adjustable range of output voltage, a small fluctuation in voltage of the capacitor, and the ability of the inductor to suppress the spike of the auxiliary balance current effectively so as to reduce the impact on the device. [ABSTRACT FROM AUTHOR]

Published

2017

5. Magnetizing-Inductance-Assisted Extended Range Soft-Switching Three-Phase AC-Link Current-Fed DC/DC Converter for Low DC Voltage Applications.

Author

Xuewei, Pan, Prasanna, Udupi R., and Rathore, Akshay

Subjects

*MAGNETIZATION, *ELECTRIC inductance, *SWITCHING circuits, *POWER electronics, *PHASE transitions, *DC-to-DC converters, *VOLTAGE-controlled oscillators, *SEMICONDUCTORS, *ELECTRIC inductors

Abstract

This paper proposes a new design with magnetizing inductance to achieve extended range soft switching of a current-sharing three-phase ac-link active-clamped zero-voltage switching (ZVS) current-fed dc/dc converter for low-voltage dc sources, i.e., battery, fuel cells, etc. The paper explains steady-state operation and presents steady-state analysis and design including magnetizing inductance effect. The proposed converter maintains ZVS of all power semiconductor devices over wide range of load and source voltage. Current sharing results in reduced peak currents and conduction losses. The proposed converter combines the merits of three-phase configuration with zero-current switching of rectifier diodes, making it a competitive topology in the area of power supplies/converters for medium power applications requiring high-voltage amplification ratio. Simulation results using PSIM 9.0 are given to verify the proposed analysis and design. An experimental converter prototype rated at 300 W has been designed, developed, and tested in the laboratory to verify and demonstrate the converter performance over wide variations in input voltage and output power for fuel cell applications. [ABSTRACT FROM PUBLISHER]

Published

2013

6. High-Performance Quasi-Z-Source Series Resonant DC?DC Converter for Photovoltaic Module-Level Power Electronics Applications.

Author

Vinnikov, Dmitri, Chub, Andrii, Liivik, Elizaveta, and Roasto, Indrek

Subjects

*POWER electronics, *PHOTOVOLTAIC power generation, *ELECTRICAL load, *PULSE width modulation, *DC-to-DC converters

Abstract

This paper presents the high-performance quasi-Z-source series resonant dc–dc converter as a candidate topology for the photovoltaic module-level power electronics applications. The converter features a wide input voltage and load regulation range thanks to the multimode operation, i.e., when the shoot-through pulse width modulation and phase-shift modulation are combined in a single switching stage to realize the boost and buck operating modes, respectively. Our experiments confirmed that the proposed converter is capable of ensuring ripple-free 400 V output voltage within the sixfold variation of the input voltage (from 10 to 60 V). The converter prototype assembled achieved a maximum efficiency of 97.4%, which includes the auxiliary power and control system losses. [ABSTRACT FROM AUTHOR]

Published

2017

7. A Comparative Study of a New ZCS DC–DC Full-Bridge Boost Converter With a ZVS Active-Clamp Converter.

Author

Mousavi, A., Das, P., and Moschopoulos, G.

Subjects

*ZERO current switching, *DC-to-DC converters, *PULSE width modulation, *ELECTRIC potential, *BRIDGE circuits, *POWER electronics

Abstract

Pulse width modulation (PWM) current-fed full-bridge dc-dc boost converters are typically used in applications where the output voltage is considerably higher than the input voltage. In this paper, a comparison is made between two converter topologies of this type-the standard zero-voltage switching (ZVS) active-clamp topology and a new zero-current switching (ZCS) topology. This paper begins with a review of the operation of the ZVS active-clamp converter and that of ZCS converters in general; the advantages and disadvantages of each approach are stated. A new ZCS-PWM current-fed dc-dc boost full-bridge converter is then introduced. The operation of the new converter is explained and analyzed, and a procedure for the design of its key components is given and demonstrated with an example. Experimental results obtained from a prototype of a ZVS active-clamp converter and the new ZCS converter are presented. Finally, a comparison of the performance of the two converters is made and conclusion based on this comparison is stated. [ABSTRACT FROM AUTHOR]

Published

2012

8. Design and Performance of a Bidirectional Isolated DC–DC Converter for a Battery Energy Storage System.

Author

Tan, Nadia Mei Lin, Abe, T., and Akagi, H.

Subjects

*DC-to-DC converters, *BATTERY storage plants, *ELECTRIC transformers, *LITHIUM-ion batteries, *MAGNETIC flux, *ELECTRIC breakdown, *POWER electronics

Abstract

This paper describes the design and performance of a 6-kW, full-bridge, bidirectional isolated dc-dc converter using a 20-kHz transformer for a 53.2-V, 2-kWh lithium-ion (Li-ion) battery energy storage system. The dc voltage at the high-voltage side is controlled from 305 to 355 V, as the battery voltage at the low-voltage side (LVS) varies from 50 to 59 V. The maximal efficiency of the dc-dc converter is measured to be 96.0% during battery charging, and 96.9% during battery discharging. Moreover, this paper analyzes the effect of unavoidable dc-bias currents on the magnetic-flux saturation of the transformer. Finally, it provides the dc-dc converter loss breakdown with more focus on the LVS converter. [ABSTRACT FROM AUTHOR]

Published

2012

9. A New Multiinput Three-Level DC/DC Converter.

Author

Dusmez, Serkan, Li, Xiong, and Akin, Bilal

Subjects

*DC-to-DC converters, *POWER electronics, *BRIDGE circuits, *ELECTRIC inductors, *ELECTRIC inductance, *RENEWABLE energy industry, *ELECTRIC potential, *ELECTRIC transformers

Abstract

Power electronics solutions based on multiple converter configurations offer cost-effective solutions by integrating a number of components at input or output power stages. This paper proposes a new multiinput isolated three-level converter for renewable and sustainable energy systems adopting high dc link voltage. Multiple dc sources are integrated to the three-level dc/dc converter before the isolation stage, resulting in reduced part-count, determining dc link voltage level and allowing flexibility in transformer design. The proposed architecture eliminates two boost switches which are present in the two-stage counterpart. The input inductors are operated in discontinuous conduction mode; thus, power can be shared between input sources through proper selection of input inductors. A low voltage prototype has been designed to serve as a proof of concept. [ABSTRACT FROM PUBLISHER]

Published

2016

10. Bidirectional Resonant DC–DC Step-Up Converters for Driving High-Voltage Actuators in Mobile Microrobots.

Author

Tang, Yichao and Khaligh, Alireza

Subjects

*RESONANCE, *DC-to-DC converters, *ELECTRIC potential, *ELECTRIC actuators, *MICROROBOTS, *ROBOT design & construction

Abstract

Electroactive polymer (EAP) actuators have been investigated to convert electrical energy into mechanical deformation in autonomous microrobots. The use of dielectric EAP actuators comes with several challenges to address requirements such as high excitation voltages, explicit driving signals, and low conversion efficiency. External bulky and heavy power sources are used to generate and provide required excitation voltages. The development of a miniature, high voltage gain, and highly efficient power electronic interface is required to overcome such challenges and enable autonomous operation of miniature robots. In this paper, a bidirectional single-stage resonant dc–dc step-up converter is introduced and developed to efficiently drive high-voltage EAP actuators in mobile microrobots. The converter utilizes resonant capacitors and a coupled inductor as a soft-switched LC network to step up low input voltage. High-frequency soft-switching operation owing to LC resonance allows small footprint of the circuit without suffering from switching losses, which in turn increases the efficiency. The circuit is capable of generating explicit high-voltage actuation signals, with capability of recovering unused energy from EAP actuators. A 4-mm × 8-mm, 100-mg, and 600-mW prototype has been designed and fabricated to drive an in-plane gap-closing electrostatic inchworm motor. Experimental validations have been carried out to verify the circuit's ability to step up voltage from 2 to 100 V and generate two 1-kHz, 100-V driving voltages at 2-nF capacitive loads. [ABSTRACT FROM PUBLISHER]

Published

2016

11. A 80-kW Isolated DC–DC Converter for Railway Applications.

Author

Baars, Nico H., Everts, Jordi, Huisman, Henk, Duarte, Jorge L., and Lomonova, Elena A.

Subjects

*DC-to-DC converters, *POWER density, *ENERGY consumption of railroads, *BRIDGE circuits, *CAPACITORS

Abstract

This paper provides an analysis of a three-phase dual active bridge (DAB) topology used as high-power-density dc–dc converter for railway applications. The three-phase DAB is analyzed concerning the current intervals, the output power, and soft-switching region, including the impact of zero-voltage switching capacitors. Furthermore, two measures are proposed to achieve soft-switching in the entire operating range, being auxiliary inductors and a straightforward switching strategy called the burst mode. Optimal component values are calculated to minimize losses in the complete operating range and to assess which measure is best suited. A prototype with the specifications acquired from the application has been built, yielding an efficiency of $95.6\%$ at a nominal output power of 80\, {\rm kW}. [ABSTRACT FROM AUTHOR]

Published

2015

12. A Novel High Step-up DC/DC Converter Based on Integrating Coupled Inductor and Switched-Capacitor Techniques for Renewable Energy Applications.

Author

Ajami, Ali, Ardi, Hossein, and Farakhor, Amir

Subjects

*DC-to-DC converters, *ELECTRIC inductors, *CAPACITORS, *RENEWABLE energy sources, *VOLTAGE multipliers, *POWER electronics

Abstract

In this paper, a novel high step-up dc/dc converter is presented for renewable energy applications. The suggested structure consists of a coupled inductor and two voltage multiplier cells, in order to obtain high step-up voltage gain. In addition, two capacitors are charged during the switch-off period, using the energy stored in the coupled inductor which increases the voltage transfer gain. The energy stored in the leakage inductance is recycled with the use of a passive clamp circuit. The voltage stress on the main power switch is also reduced in the proposed topology. Therefore, a main power switch with low resistance RDS(ON) can be used to reduce the conduction losses. The operation principle and the steady-state analyses are discussed thoroughly. To verify the performance of the presented converter, a 300-W laboratory prototype circuit is implemented. The results validate the theoretical analyses and the practicability of the presented high step-up converter. [ABSTRACT FROM AUTHOR]

Published

2015

13. General Analysis and Design Guideline for a Battery Buffer System With DC/DC Converter and EDLC for Electric Vehicles and its Influence on Efficiency.

Author

Schroeder, Jens Christian and Fuchs, Friedrich Wilhelm

Subjects

*ELECTRIC batteries, *DC-to-DC converters, *ELECTRIC vehicles, *ELECTRIC double layer, *CAPACITORS, *ACCELERATION (Mechanics)

Abstract

In this paper, the general design of a battery buffer system (BBS) consisting of a dc/dc converter and electric double layer capacitors for an electric vehicle is presented. This is intended to save the regenerative braking energy and to support the battery during acceleration. The design of a multiphase converter in interleaved operation with nonideal coupled inductors is stated to minimize volume and power losses while maintaining given current ripple limitations. A reduced sensor current-sharing control method is developed and its correct choice of the sensor position is explained. The peak efficiency of the designed and built converter can be measured to nearly 99%. The corresponding BBS is implemented in a lead-acid battery powered electric lift truck propulsion system. The system operation with and without the BBS is compared to examine the behavior and the overall efficiency. It can be shown that the traction battery stress can be strictly reduced as well as the temperature rise in the battery. Furthermore, the efficiency can be increased in the range of 5-6%. The battery's lifetime improvement is estimated by means of the difference in the temperature rise to approximately 20%. [ABSTRACT FROM AUTHOR]

Published

2015

14. Generalized Technique of Compensating Low-Frequency Component of Load Current With a Parallel Bidirectional DC/DC Converter.

Author

Dusmez, Serkan and Khaligh, Alireza

Subjects

*DC-to-DC converters, *ELECTRIC vehicles, *POWER factor measurement, *BATTERY chargers, *SUPERCAPACITORS

Abstract

The first stage of a battery charger in electric vehicles is a power factor correction (PFC) circuit, which creates a second harmonic in the dc link. This harmonic is typically filtered through a bulky dc-link capacitor. In the conventional battery chargers, another dc/dc stage is utilized to regulate the battery current. In this paper, the second harmonic in the dc link is analyzed in detail and a new load current compensation technique is proposed. The proposed technique replaces the second stage dc/dc converter with a bidirectional dc/dc converter connected in parallel with the load, and requires a secondary energy source, i.e., a small-size capacitor. The capacitor injects 180° phase-shifted second harmonic current to the dc link. Thus, the dc-link capacitor can be reduced significantly as it is only sized for high-frequency ripples rather than being sized for low-frequency content. The proposed method is generalized for resistive and battery loads with voltage- and current-source PFC circuits. A 360 W prototype is developed to experimentally verify the proposed technique. A 72 V/10 A·h battery module is charged by filtering an oscillating power of 360 W using a two-quadrant bidirectional dc/dc converter and an UC module, demonstrating a peak charging current of 16 A. [ABSTRACT FROM AUTHOR]

Published

2014

15. Efficiency Characterization and Impedance Modeling of a Multilevel Switched-Capacitor Converter Using Pulse Dropping Switching Scheme.

Author

Alam, Mohammed Khorshed and Khan, Faisal H.

Subjects

*CAPACITOR switching, *ELECTRIC impedance, *VOLTAGE regulators, *DC-to-DC converters, *ELECTRONIC modulation, *POWER electronics

Abstract

A pulse dropping switching technique (PDT) has been presented in this paper to accomplish variable conversion ratio (CR) in a multilevel modular capacitor-clamped dc-dc converter in the step-up conversion mode. The switching pattern is generated by comparing a triangular wave with a rectangular wave, and a proper output voltage regulation can be obtained by controlling the relative frequency and amplitude of these two waveforms. A state-space modeling technique has been applied here to estimate the variation in equivalent output resistance (EOR) for different operating conditions of the PDT. The EOR can be varied in a wide range without changing the operating frequency of the converter, and thereby the PDT enhances the degrees of freedom to accomplish voltage regulation in a two-phase switched-capacitor converter. Slow-switching limit of the converter has been derived to define the boundary of the EOR. Different challenges and limitations of the proposed modulation scheme has been discussed in detail, and the proposed analysis has been verified by comparing the analytical expressions with the simulation and experimental results for different switching frequencies, modulation indices, and number of active modules. In addition, variations in the CR, efficiency and ripple voltage for different number of active modules and switching conditions have been described in detail. [ABSTRACT FROM AUTHOR]

Published

2014

16. Assessment of Coupled and Independent Phase Designs of Interleaved Multiphase Buck/Boost DC–DC Converter for EV Power Train.

Author

Pavlovsky, Martin, Guidi, Giuseppe, and Kawamura, Atsuo

Subjects

*DC-to-DC converters, *AUTOMOBILE power trains, *ELECTRIC filters, *ELECTRIC vehicles, *COMPUTER-aided design, *POWER electronics

Abstract

The paper discusses two approaches to multiphase nonisolated dc-dc converter design. An approach based on independent phases is directly compared to an approach using coupled phases. The comparison is performed through theoretical analysis of respective conversion functions, input and output filter requirements, and required input inductor size. Three-dimensional (3-D) high-power-density computer aided design (CAD) models and full-scale 56 kW prototypes based on both approaches were designed, built, and experimentally compared. As expected, the approach with independent phases has a considerable advantage regarding the low-power conversion efficiency where the efficiency can be up to 2% higher than with the coupled approach. On the other hand, the design with coupled inductors can reach power density as high as two times that of the independent phase design (87 kW/L versus 44.2 kW/L). Therefore, the use of coupled inductors may be very beneficial for space critical applications. In case of the electric vehicle power train, both factors may be very important and the suitable approach should be chosen based on system design priorities. [ABSTRACT FROM AUTHOR]

Published

2014

17. Novel Transformerless Grid-Connected Power Converter With Negative Grounding for Photovoltaic Generation System.

Author

Jia-Min Shen, Hurng-Liahng Jou, and Jinn-Chang Wu

Subjects

*ELECTRON tube grids, *DC-to-DC converters, *PHOTOVOLTAIC power generation, *DC-AC converters, *ELECTRIC switchgear, *ELECTRIC inverters, *POWER electronics

Abstract

This paper proposes a novel transformerless grid-connected power converter with negative grounding for a photovoltaic generation system. The negative terminal of the solar cell array can be directly connected to the ground in the proposed grid-connected power converter to avoid the transparent conducting oxide corrosion that occurs in some types of thin-film solar cell array. The proposed grid-connected power converter consists of a dc-dc power converter and a dc-ac inverter. The salient features of the proposed power converter are that some power electronic switches are simultaneously used in both the dc-dc power converter and dc-ac inverter, and only two power electronic switches operate at high switching frequency at the same time (one is in the dc-dc power converter and the other is in the dc-ac inverter). The leakage current of the photovoltaic generation system is reduced because the negative terminal of the solar cell array is connected directly to the ground. Finally, a prototype was developed to verify the performance of the proposed grid-connected power converter. The experimental results show that the performance of the proposed grid-connected power converter is as expected. [ABSTRACT FROM AUTHOR]

Published

2012

18. A Safety Enhanced, High Step-Up DC–DC Converter for AC Photovoltaic Module Application.

Author

Shih-Ming Chen, Tsorng-Juu Liang, Lung-Sheng Yang, and Jiann-Fuh Chen

Subjects

*DC-to-DC converters, *PHOTOVOLTAIC power generation, *HIGH voltages, *DC-AC converters, *VOLTAGE-frequency converters, *POWER electronics

Abstract

Within the photovoltaic (PV) power-generation market, the ac PV module has shown obvious growth. However, a high voltage gain converter is essential for the module's grid connection through a dc-ac inverter. This paper proposes a converter that employs a floating active switch to isolate energy from the PV panel when the ac module is off; this particular design protects installers and users from electrical hazards. Without extreme duty ratios and the numerous turns-ratios of a coupled inductor, this converter achieves a high step-up voltage-conversion ratio; the leakage inductor energy of the coupled inductor is efficiently recycled to the load. These features explain the module's high-efficiency performance. The detailed operating principles and steady-state analyses of continuous, discontinuous, and boundary conduction modes are described. A 15 V input voltage, 200 V output voltage, and 100 W output power prototype circuit of the proposed converter has been implemented; its maximum efficiency is up to 95.3% and full-load efficiency is 92.3%. [ABSTRACT FROM AUTHOR]

Published

2012

19. Optimization and Design of a Cascaded DC/DC Converter Devoted to Grid-Connected Photovoltaic Systems.

Author

Vighetti, S., Ferrieux, J-P, and Lembeye, Y.

Subjects

*DC-to-DC converters, *PHOTOVOLTAIC power generation, *ELECTRON tube grids, *ELECTRIC potential, *MATHEMATICAL optimization, *QUADRATIC programming, *POWER electronics

Abstract

The integration of photovoltaic (PV) modules in buildings causes problems with shadows that can strongly reduce the energy produced by these systems. Moreover, most PV modules are designed for stand-alone applications that have output voltage adapted to lead batteries. Indeed, this historical sizing of PV modules can be discussed in the case of grid-connected systems. In this paper, a cascaded dc/dc converter based on boost chopper is proposed. First, the advantages and the limits of this topology will be shown. Second, this topology will be optimized to maximize the efficiency or minimize the volume. The originality of this optimization is that the converters' parameters and the arrangement of the PV cells are variable parameters. Indeed, the optimization is done on the entire system. To realize these optimizations, semiempiric models of losses and volumes of different components of a boost chopper were developed. The optimization uses a successive quadratic programming algorithm. Considering the optimization results over the whole range of the specifications, a flexible solution is developed and experimental results are presented. Finally, optimized topologies connected to several PV are evaluated at different situations of typical shadows. [ABSTRACT FROM AUTHOR]

Published

2012

20. 55-kW Variable 3X DC-DC Converter for Plug-in Hybrid Electric Vehicles.

Author

Wei Qian, Honnyong Cha, Fang Zheng Peng, and Tolbert, L. M.

Subjects

*DC-to-DC converters, *PLUG-in hybrid electric vehicles, *ELECTRIC inverters, *CAPACITORS, *ELECTRIC inductance, *ELECTRIC potential, *POWER electronics

Abstract

This paper presents an alternative to the traditional dc-dc converter interfacing the battery with the inverter dc bus in plug-in hybrid electric vehicle (HEV) traction drives. The boost converter used in commercial HEVs meets with obstacles when it comes to upgrading the power rating and achieving high efficiency while downsizing the converter. A four-level flying-capacitor dc-dc converter is explored that can overcome these drawbacks by dramatically reducing the inductance requirement. A special case of the four-level converter, the 3X dc-dc converter, operates at three discrete output/input voltage ratios, thus further reducing the inductance requirement to a minimal value (almost zero). When further compared to its switched-capacitor dc-dc converter counterparts, the 3X dc-dc converter can be operated at variable output/input voltage ratios without sacrificing efficiency, and it lowers the capacitance requirement by utilizing the parasitic inductance. The operating principle, current ripple analysis, the transient control to limit the inrush current, and power loss analysis are introduced. Experimental results of a 55-kW prototype are provided to demonstrate the principle and analysis of this topology. [ABSTRACT FROM AUTHOR]

Published

2012