Showing total 1,613 results

151. Dual-Output Boost Resonant Full-Bridge Topology and its Modulation Strategies for High-Performance Induction Heating Applications.

Author

Sarnago, Hector, Lucia, Oscar, Perez-Tarragona, Mario, and Burdio, Jose M.

Subjects

INDUCTION heating, HOUSEHOLD appliances, CASCADE converters, HOUSEHOLD appliances industry, ELECTRONIC modulation

Abstract

Induction heating (IH) is a key technology in modern household appliances and industries. Modern design trends require the design of high efficiency and multiple output power converters. This paper proposes a dual-output boost resonant full-bridge topology to provide a multiple-output converter with improved performance while keeping a cost-effective performance. The proposed converter is detailed and analyzed, and several modulation strategies are proposed to obtain proper output power control. Finally, an experimental prototype is built, verifying the proper operation and performance of the proposed topology. [ABSTRACT FROM PUBLISHER]

Published

2016

152. Novel Discontinuous PWM Method of a Three-Level Inverter for Neutral-Point Voltage Ripple Reduction.

Author

Lee, June-Seok, Yoo, Seungjong, and Lee, Kyo-Beum

Subjects

PULSE width modulation transformers, ELECTRIC inverters, VOLTAGE regulators, ELECTRIC waves, ELECTRIC potential

Abstract

A new pulsewidth modulation (PWM) strategy which is an alternative approach of the discontinuous PWM (DPWM) for a three-level neutral-point-clamped (NPC) inverter is proposed in this paper. A three-level NPC inverter is completely mature and very well-established topology in high-power applications. However, the three-level NPC inverter has an inheritance problem of the neutral-point voltage unbalancing due to the split dc-link capacitors. This structure can cause large neutral-point voltage ripple. Furthermore, output currents of the three-level NPC inverter are distorted by the neutral-point voltage ripple. Therefore, the neutral-point voltage must be controlled. In this paper, a new DPWM method using two different offsets for the neutral-point ripple reduction is proposed and the effectiveness of the proposed DPWM method is verified by using the simulation and the experimental results. [ABSTRACT FROM PUBLISHER]

Published

2016

153. Wide ZVS Range Asymmetric Half-Bridge Converter With Clamp Switch and Diode for High Conversion Efficiency.

Author

Yeon, Cheol-O, Lee, Jae-Bum, Lee, Il-Oun, and Moon, Gun-Woo

Subjects

ELECTRIC current converters, DC-to-DC converters, ZERO voltage switching, CLAMPING circuits, PULSE width modulation

Abstract

A conventional asymmetrical half-bridge (AHB) converter is widely used for dc–dc stage in low-to-medium power system. However, since the asymmetric operation of AHB converter causes the low efficiency over entire load condition, the conventional AHB converter is not usually considered for the candidate of server power system. In order to overcome the problems of the conventional AHB converter, a wide zero-voltage-switching (ZVS) range AHB converter with a clamp switch and a clamp diode is proposed in this paper. The proposed AHB converter (PAHBC) replaces a low-side clamp diode with a MOSFET switch and adds an auxiliary winding, which changes the transformer turns-ratio. From these modifications and the pulsewidth-modulation (PWM) control of clamp switch, the PAHBC can be designed optimally at nominal input condition and obtains additional dc gain at hold-up time condition. These advantages achieve the high conversion efficiency over the entire load condition. The operational principle and analysis of the PAHBC are presented in this paper and verified by a 340–400 V input and 50 V/500 W output laboratory prototype. [ABSTRACT FROM PUBLISHER]

Published

2016

154. Design and Analysis of a New Evaluation Circuit for Capacitors Used in a High-Power Three-Phase Inverter.

Author

Hasegawa, Kazunori, Omura, Ichiro, and Nishizawa, Shin-ichi

Subjects

CAPACITORS, DIRECT currents, ELECTRIC inverters, ELECTRIC circuits, ELECTRIC waves

Abstract

DC-link capacitors in power electronic converters are a major constraint on improvement of power density as well as reliability. Evaluation of the dc-link capacitors in terms of power loss, ageing, and failure rate will play an important role in design stages of the next-generation power converters. This paper proposes a new evaluation circuit for dc-link capacitors used in a high-power three-phase inverter, which is intended for testing power loss, failure rate, ageing, and so on. The evaluation circuit produces a practical ripple current waveform and a dc bias voltage into a capacitor under test, in which the ripple current is equivalent to that generated by the three-phase inverter on the dc link. The evaluation circuit employs a full-scale current-rating and downscaled voltage-rating inverter for producing the ripple current, so that the power rating of the evaluation circuit is much smaller than that of a full-scale current-rating and full-scale voltage-rating inverter. Theoretical analysis and simulated results verify the effectiveness of new evaluation circuit. [ABSTRACT FROM PUBLISHER]

Published

2016

155. Study of a Novel Equivalent Model and a Long-Feeder Simulator-Based Active Power Filter in a Closed-Loop Distribution Feeder.

Author

Sun, Xiaofeng, Han, Ruijing, Yang, Lili, Shen, Hong, Tian, Yanjun, Guo, Xiaoqiang, and Chen, Zhe

Subjects

ELECTRIC power distribution, CLOSED loop systems, ELECTRICAL harmonics, ELECTRIC power filters, ELECTRIC power factor correction, CAPACITORS

Abstract

The closed-loop distribution system has become a trend, owing to increasing demands of electric power reliability in high-tech parks or in metropolitan areas. Harmonic propagation caused by power-factor correction capacitors and system inductors may lead to significant harmonic amplification throughout a closed-loop distribution feeder. This paper proposes a novel equivalent model of a closed-loop distribution feeder that a closed-loop distribution feeder can be equivalent to a radial feeder. This paper analyzes the harmonic propagation in a closed-loop distribution feeder and proposes a long-feeder simulator-based active power filter (LFS-APF) to damp out the harmonic propagation, based on the novel equivalent model. The proposed LFS-APF is installed at the middle point of a closed-loop feeder. The LFS-APF has better capability of harmonic damping than the resistive APF (RAPF), especially in response to variation of both nonlinear loads and power-factor correction capacitors or even if the installation location has to deviate from the middle point. Both simulation and experiment results are provided to validate the correctness and effectiveness of the novel equivalent model and the proposed LFS-APF. [ABSTRACT FROM PUBLISHER]

Published

2016

156. Decoupled DC-Link Capacitor Voltage Control of DC–AC Multilevel Multileg Converters.

Author

Busquets-Monge, Sergio, Grino, Robert, Nicolas-Apruzzese, Joan, and Bordonau, Josep

Subjects

CAPACITORS, CAPACITOR motors, ELECTRIC potential measurement, ELECTRIC controllers, SIMULATION methods & models

Abstract

This paper studies the coupling between the capacitor voltage control loops of diode-clamped (or functionally equivalent) multilevel multileg (multiphase) dc–ac converters. From a complete model of the plant revealing the coupling, a simple approach consisting in multiplying the vector of control commands by a constant matrix is proposed to decouple the control problem and achieve a better controller performance. Simulation and experimental results are presented to prove the superior performance of the proposed decoupled control. [ABSTRACT FROM PUBLISHER]

Published

2016

157. A Peak-Capacitor-Current Pulse-Train-Controlled Buck Converter With Fast Transient Response and a Wide Load Range.

Author

Sha, Jin, Xu, Duo, Chen, Yiming, Xu, Jianping, and Williams, Barry W.

Subjects

DC-to-DC converters, PULSE width modulation, ITERATIVE methods (Mathematics), ELECTRIC currents, SIMULATION methods & models

Abstract

It is known that the ripple-based control of a switching dc–dc converter benefits from a faster transient response than a conventional pulse width modulation (PWM) control switching dc–dc converter. However, ripple-based control switching dc–dc converters may suffer from fast-scale oscillation. In order to achieve fast transient response and ensure the stable operation of a switching dc–dc converter over a wide load range, based on a conventional pulse train (PT) control technique, a peak capacitor current PT (PCC-PT) control technique is proposed in this paper. With a buck converter as an example, the operating modes, steady-state performance, and transient respond performance of a PCC-PT controlled buck converter are presented and assessed. To eliminate fast-scale oscillation, circuit and control parameter design considerations are given. An accurate discrete iteration model of a PCC-PT controlled buck converter is established, based on which the effects of circuit parameters on the stability of the converter operating in a discontinuous current mode (DCM), mixed DCM-continuous conduction mode (CCM), and CCM are studied. Simulation and experimental results are presented to verify the analysis results. [ABSTRACT FROM PUBLISHER]

Published

2016

158. Highly Reliable Transformerless Photovoltaic Inverters With Leakage Current and Pulsating Power Elimination.

Author

Tang, Yi, Yao, Wenli, Loh, Poh Chiang, and Blaabjerg, Frede

Subjects

ELECTRIC inverters, PHOTOVOLTAIC power systems, STRAY currents, ELECTRIC capacity, CLOSED loop systems

Abstract

This paper presents a transformerless inverter topology, which is capable of simultaneously solving leakage current and pulsating power issues in grid-connected photovoltaic (PV) systems. Without adding any additional components to the system, the leakage current caused by the PV-to-ground parasitic capacitance can be bypassed by introducing a common-mode (CM) conducting path to the inverter. The resulting ground leakage current is therefore well controlled to be below the regulation limit. Furthermore, the proposed inverter can also eliminate the well-known double-line-frequency pulsating power that is inherent in single-phase PV systems. By properly injecting CM voltages to the output filter capacitors, the pulsating power can be decoupled from the dc-link. Therefore, it is possible to use long-lifetime film capacitors instead of electrolytic capacitors to improve the reliability of the PV system. The mechanism of leakage current suppression and the closed-loop control of pulsating power decoupling are discussed in this paper in detail. A 500-W prototype was also built and tested in the laboratory, and both simulation and experimental results are finally presented to show the excellent performance of the proposed PV inverter. [ABSTRACT FROM PUBLISHER]

Published

2016

159. Phase-Shifted Carrier Modulation Techniques for Cascaded H-Bridge Multilevel Converters.

Author

Townsend, Christopher D., Summers, Terrence J., and Betz, Robert E.

Subjects

ELECTRONIC modulation, VOLTAGE control, CAPACITORS, CASCADE converters, BRIDGE circuits, PHASE shift (Nuclear physics), SEMICONDUCTOR devices

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, until now, its implementation has necessitated a capacitor voltage balancing scheme that degrades converter harmonic performance. This paper develops two phase-shifted carrier modulation schemes that avoid harmonic degradation by exploiting an extra degree of freedom in the available switching states. Simulation and experimental results are presented that confirm the correct operation of the modulation strategies. [ABSTRACT FROM PUBLISHER]

Published

2015

160. Impact of Grid Asymmetries on the Operation and Capacitive Energy Storage Design of Modular Multilevel Converters.

Author

Vasiladiotis, Michail, Cherix, Nicolas, and Rufer, Alfred

Subjects

CASCADE converters, ELECTRIC power distribution grids, ENERGY storage, OSCILLATIONS, HARMONIC analyzers, CAPACITORS

Abstract

The grid-connected modular multilevel converter (MMC) is very likely to operate under asymmetric grid conditions. Such a converter features several unique characteristics, which make its analysis different from other types of power converters in similar cases. In this paper, the three well-established control techniques, i.e., balanced current and negative sequence current injection for active/reactive power oscillation elimination, are tailored for the MMC case taking into account grid current limitation under fault conditions. Since the focus is laid on the MMC design impact during grid asymmetries, the three methods are compared in terms of branch energy variation increase as well as maximum achievable active power transfer. Moreover, the effect of circulating current second-order harmonic injection for capacitive storage reduction as well as dc-link oscillation elimination is also studied. Finally, experimental results from a downscaled laboratory prototype verify the theoretical studies. [ABSTRACT FROM PUBLISHER]

Published

2015

161. A Three-Phase AC–AC Converter in Open-Delta Connection Based on Switched Capacitor Principle.

Author

Vecchia, Mauricio Dalla, Lazzarin, Telles Brunelli, and Barbi, Ivo

Subjects

AC-AC transformers, EQUIVALENT electric circuits, PHASOR measurement, CAPACITOR switching, CAPACITORS

Abstract

This paper proposes a new topology for a three-phase open-delta connection ac–ac converter based on the switched capacitor principle. The topology employs only capacitors and switches in the power stage, which can provide high efficiency and power density. It operates in open loop with constant values for the gain, duty cycle, and frequency. The converter is bidirectional and thus it can step-down or step-up the output voltages. A 3.5-kW prototype was built, tested and used to verify the theoretical analysis for resistive, inductive, and nonlinear loads. The efficiency of the topology is around 93% in nominal load and the power density is 1.178 kW/kg. [ABSTRACT FROM PUBLISHER]

Published

2015

162. Input-Series and Output-Series Connected Modular Output Capacitor Full-Bridge PWM DC–DC Converter.

Author

Bottion, Antonio J. B. and Barbi, Ivo

Subjects

CONVERTERS (Electronics), CAPACITORS, HIGH voltages, SERIES electric circuits, CASCADE converters

Abstract

This paper proposes a modular isolated dc–dc converter, based on the input-series and output-series association of the full-bridge PWM dc–dc converter with capacitive filter. The main attribute of the proposed architecture is its ability to provide self-balance of the input and output voltages across the individual converters, without voltage loop control scheme, both in the steady-state and transient operations. Circuit operation, theoretical analysis, and modeling are included in this paper, along with experimental results taken from a laboratory prototype with four modules, 1600-Vdc total input voltage, 1600-Vdc total output voltage, 4-kW output power, and 40-kHz switching frequency. Possible applications include high-voltage power supplies, solid-state transformers, dc current distribution systems, and renewable electric energy systems. [ABSTRACT FROM PUBLISHER]

Published

2015

163. Operation and Control of an Improved Performance Interactive DSTATCOM.

Author

Kumar, Chandan and Mishra, Mahesh K.

Subjects

ELECTRIC power distribution, ELECTRIC power factor, VOLTAGE control, SYNCHRONOUS capacitors, ELECTRIC power systems research

Abstract

This paper proposes an improved performance interactive distribution static compensator (DSTATCOM) to address the limitations of conventional current control mode (CCM) and voltage control mode (VCM) operations. The proposed interactive scheme provides smooth transfer of modes of operation while remaining connected in the distribution system. In normal operation, the DSTATCOM operates in CCM to make source currents balanced, sinusoidal, and at a unity power factor. During voltage disturbances, the CCM operation cannot improve load voltage. In that case, DSTATCOM operation is changed to VCM, which maintains a constant voltage across the sensitive loads. Hence, this interactive DSTATCOM ensures continuous, flexible, and robust operation of the load. Moreover, the filter current requirements are reduced in the proposed scheme, which reduces the losses in the filter and feeder, improves inverter efficiency, and requires a reduced-rating inverter for sag mitigation. The principle of operation and control for both operating modes is analyzed. The detailed process of the flexible transfer between the two modes is derived. Deadbeat predictive control algorithms for CCM as well as VCM operation are developed for fast operation during mode transfers. The performance of the proposed scheme is validated by both simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2015

164. Control and Stability Analysis of Modular Multilevel Converter Under Low-Frequency Operation.

Author

Debnath, Suman, Qin, Jiangchao, and Saeedifard, Maryam

Subjects

MULTILEVEL models, CONVERTERS (Electronics), ELECTRIC power conversion, LYAPUNOV functions, PERTURBATION theory, CAPACITORS

Abstract

The modular multilevel converter (MMC) is increasingly becoming popular for multi-MW drive systems. One of the main technical challenges associated with the operation of MMC for adjustable-speed drives is the large magnitude of submodule (SM) capacitor voltage ripple under constant-torque low-speed operation. This paper proposes two new control strategies to reduce the magnitude of the SM capacitor voltage ripple in the MMC-based adjustable-speed drive systems under constant-torque low-speed operation. The proposed control strategies are based on injecting a square-wave common-mode voltage at the ac-side and a circulating current within the phase-legs to attenuate the low-frequency components of the SM capacitor voltages. The frequency spectrum of the injected circulating current consists of components in the vicinity of either the common-mode frequency or the common-mode frequency and third harmonic of the common-mode frequency. This paper also provides: i) a theoretical comparison of the proposed control strategies with the existing ones; ii) a controller design methodology to systematically determine the controller gains of the proposed control strategies; and iii) a theoretical proof of stability of the proposed control strategies and their design methodology based on Lyapunov analysis of singularly perturbed nonlinear non-autonomous systems. A set of experimental results for various case studies on a laboratory-scale prototype are provided to support the theoretical proof of stability of the proposed control strategies and their design methodology, and to show the superior performance of the proposed strategies over the existing strategy. [ABSTRACT FROM PUBLISHER]

Published

2015

165. Electric Field Sensor Based on Piezoelectric Bending Effect for Wide Range Measurement.

Author

Xue, Fen, Hu, Jun, Wang, Shan X., and He, Jinliang

Subjects

CAPACITIVE sensors, PIEZOELECTRICITY, SENSOR networks, SENSITIVITY analysis, PIEZOELECTRIC materials

Abstract

In this paper, we report on the new design of an electric field sensor based on piezoelectric bending effect in a capacitive-sensing method. The bipolar electric field sensor with a range from −22 to 22 kV/cm concentrates on a bending structure to enlarge the piezoelectric effect and to control its bending orientation. It performs with a much higher sensitivity of 0.448 pF/(kV/cm) or 5.78%/(kV/cm) and has a better resolution of 7.0 V/cm at $E=0$. Factors influencing the capacitance response are also discussed, which might further optimize the sensitivity. Moreover, the analytical model and experimental results make an agreement on the reasonability of this electric field sensor, gaining an insightful guide to the potential capacitive-sensing electric field chip sensor widely distributed in sensor networks. [ABSTRACT FROM PUBLISHER]

Published

2015

166. Low-Order Harmonic Suppression for Open-End Winding IM With Dodecagonal Space Vector Using a Single DC-Link Supply.

Author

Pramanick, Sumit, Azeez, Najath Abdul, Sudharshan Kaarthik, R., Gopakumar, K., and Cecati, Carlo

Subjects

PULSE width modulation transformers, HARMONIC suppression filters, VECTOR spaces, PULSE width modulation, CAPACITORS

Abstract

This paper proposes a technique to suppress low-order harmonics for an open-end winding induction motor drive for a full modulation range. One side of the machine is connected to a main inverter with a dc power supply, whereas the other inverter is connected to a capacitor from the other side. Harmonic suppression (with complete elimination of fifth- and seventh-order harmonics) is achieved by realizing dodecagonal space vectors using a combined pulsewidth modulation (PWM) control for the two inverters. The floating capacitor voltage is inherently controlled during the PWM operation. The proposed PWM technique is shown to be valid for the entire modulation range, including overmodulation and six-step mode of operation of the main inverter. Experimental results have been presented to validate the proposed technique. [ABSTRACT FROM PUBLISHER]

Published

2015

167. An Energy Stored Quasi-Z-Source Cascade Multilevel Inverter-Based Photovoltaic Power Generation System.

Author

Sun, Dongsen, Ge, Baoming, Liang, Weihua, Abu-Rub, Haitham, and Peng, Fang Zheng

Subjects

PHOTOVOLTAIC power systems, PHOTOVOLTAIC power generation, QUASIANALYTIC functions, ELECTRIC inverters, ENERGY storage

Abstract

The quasi-Z-source cascade multilevel inverter (qZS-CMI) presents many advantages over conventional CMI when applied in photovoltaic (PV) power systems. For example, the qZS-CMI provides the balanced dc-link voltage and voltage boost ability, saves one-third modules, etc. However, the qZS-CMI still cannot overcome the intermittent and stochastic fluctuation of solar power injected to the grid. This paper proposes an energy stored qZS-CMI-based PV power generation system. The system combines the qZS-CMI and energy storage by adding an energy stored battery in each module to balance the stochastic fluctuations of PV power. This paper also proposes a control scheme for the energy stored qZS-CMI-based PV system. The proposed system can achieve the distributed maximum power point track for PV panels, balance the power between different modules, and provide the desired power to the grid. A detailed design method of controller parameters is disclosed. Simulation and experimental results verify the proposed system and the control scheme. [ABSTRACT FROM PUBLISHER]

Published

2015

168. Single-Switch Multichannel Current-Balancing LED Drive Circuits Based on Optimized SC Techniques.

Author

Ye, Yuanmao, Cheng, Ka Wai Eric, Lin, Jiongkang, and Wang, Daohong

Subjects

SWITCHING power supplies, SWITCHED capacitor circuits, LIGHT emitting diodes, MAGNETIC devices, PULSE width modulation transformers

Abstract

By combining the conventional switched-mode power converters with advanced switched capacitor (SC) techniques, a plurality of single-switch current-balancing circuits is developed to drive multiple light-emitting diode (LED) strings in this paper. Compared with the existing current-balancing LED drivers, the proposed drive circuits exhibit their attractive advantages in size and cost efficiency because just one active switch and one magnetic device are required. LED strings' current can be regulated by controlling the duty ratio of the switch in pulsewidth-modulation mode. Both advanced resonant and nonresonant SC methods are introduced to optimize the performance of the proposed LED drivers. The feasibility and theoretical analysis are verified with a 9-W dual-channel nonisolated prototype and a 25-W four-channel isolated prototype. [ABSTRACT FROM PUBLISHER]

Published

2015

169. Ozone-Driven Circuit Design Enhanced With an Improved Half-Bridge Inverter of Wide-Input-Voltage Capability.

Author

Huang, Shyh-Jier, Hung, Te-Chun, and Lin, Chun-Wei

Subjects

ELECTRIC inverters, ELECTRIC circuits, ELECTRIC current converters, ELECTRIC generators, IDEAL sources (Electric circuits)

Abstract

This paper proposes an improved half-bridge inverter with wide-input-voltage capability for ozone-driven circuits. The study is motivated because the limited regulation of input voltage often affects the operation flexibility of ozone-driven circuits. Therefore, a modification of a half-bridge inverter along with a multiwinding coil design is proposed in this study, anticipating an increase in the range of input voltage and benefiting the industry applications. To confirm the practicality of this method, a hardware circuit was made with extensive validation. Experimental outcomes support the feasibility of this proposed method for ozone generators, exhibiting a potential of the method extending to other voltage-source applications. [ABSTRACT FROM PUBLISHER]

Published

2015

170. Novel High-Conversion-Ratio High-Efficiency Isolated Bidirectional DC–DC Converter.

Author

Liang, Tsorng-Juu and Lee, Jian-Hsieng

Subjects

DC-to-DC converters, ELECTRIC current converters, ELECTRIC power conversion, CAPACITORS, NUCLEAR energy, EQUIPMENT & supplies

Abstract

This paper proposes a novel high-conversion-ratio high-efficiency isolated bidirectional dc–dc converter. The proposed converter is operated in the step-down stage. The dc-blocking capacitor in the high-voltage side is used to reduce the voltage on the transformer, and the current-doubler circuits are used in the low-voltage side to reduce the output current ripple. The energy stored in the leakage inductance is recycled to the dc-blocking capacitor. When the proposed converter is operated with a step-up function, dual current-fed circuits on the low-voltage side are used to reduce the current ripples and conduction losses of the switches in the low-voltage side. The voltage-doubler circuit in the high-voltage side increases the conversion ratio. The proposed converter can achieve high conversion with high efficiency. Experimental results based on a prototype implemented in the laboratory with a high voltage of 200 V, low voltage of 24 V, and output power of 200 W verify the performance of the proposed converter. The peak efficiency of the proposed converter in the high-step-down and high-step-up stages is 96.3% and 95.6%, respectively. [ABSTRACT FROM PUBLISHER]

Published

2015

171. Self-Excited Induction Generator as an Auxiliary Brake for Heavy Vehicles and Its Analog Controller.

Author

Bae, Jae-Nam, Kim, Yong-Eun, Son, Young-Wook, Moon, Hee-Seok, Yoo, Chang-Hee, and Lee, Ju

Subjects

ELECTRIC vehicles, ELECTRIC generators, MAGNETIC brakes, ELECTRIC circuits, BRAKE systems

Abstract

A self-excited induction generator (SEIG) can be a candidate for isolated applications because it does not require any external exciting power but can independently generate electricity. It is also a good candidate for auxiliary brakes in heavy vehicles for several reasons. First, the power efficiency in a brake system is not important as compared with motors or generators. Second, an SEIG can be controlled by a simple electrical circuit. Third, it can be used for regenerative braking. Finally, it is very robust. In this paper, an auxiliary brake for heavy vehicles is proposed by adapting an SEIG and its analog control circuit. The brake structure is the same as that in conventional eddy current brakes but operates as an SEIG. The suggested control circuit does not adopt an electric controller unit but only consists of simple electric devices. A miniature model was designed and manufactured, and the experimental results using the prototype verify that the proposed brake system, including the controller, is very useful. [ABSTRACT FROM PUBLISHER]

Published

2015

172. Enhanced DC-Link Capacitor Voltage Balancing Control of DC–AC Multilevel Multileg Converters.

Author

Busquets-Monge, Sergio, Maheshwari, Ramkrishan, Nicolas-Apruzzese, Joan, Lupon, Emili, Munk-Nielsen, Stig, and Bordonau, Josep

Subjects

ELECTRIC current converters, ELECTRIC power conversion, CAPACITORS, ELECTRIC potential, VOLTAGE control

Abstract

This paper presents a capacitor voltage balancing control applicable to any multilevel dc–ac converter formed by a single set of series-connected capacitors implementing the dc link and semiconductor devices, such as the diode-clamped topology. The control is defined for any number of dc-link voltage levels and converter legs (for single-phase and multiphase systems), guaranteeing the capacitor voltage control for any modulation index value and load (from idle mode to full power). The associated control loop small-signal transfer function is presented, from which optimum compensator design guidelines are derived. The improvement in control performance is verified through simulation and experiments comparing with a previous balancing control strategy in a four-level three-phase dc–ac conversion system. The satisfactory control performance is also verified through simulation in a four-level five-phase dc–ac conversion system. [ABSTRACT FROM PUBLISHER]

Published

2015

173. A PSO-Based Fuzzy-Controlled Searching for the Optimal Charge Pattern of Li-Ion Batteries.

Author

Wang, Shun-Chung and Liu, Yi-Hua

Subjects

PARTICLE swarm optimization, ELECTRIC capacity, CAPACITORS, CONSTANT current sources

Abstract

This paper proposes a searching strategy based on particle swarm optimization, combined with a fuzzy-deduced fitness evaluator (FDFE), to find the optimal multistage charging pattern that delivers the most discharged capacity within the shortest charging time (CT). The objective function of the optimization problem is to maximize the cost effectiveness for the applied charging pattern based on the CT and normalized discharged capacity (NDC). Therefore, this paper proposes an FDFE to combine CT and NDC into a unified cost function to properly evaluate the multiple performance characteristics index in the charge problem. The experimental results show that the obtained pattern is capable of charging the batteries to over 88% capacity within 51 min. Compared with the conventional constant current–constant voltage method, the CT, the obtained life cycle, and the charging efficiency of the lithium-ion (Li-ion) battery for the devised approach are improved by approximately 56.8%, 21%, and 0.4%, respectively. The presented charging approach is suitable for the increasingly applications, in which the batteries are “sealed” inside the products to extend the life span. [ABSTRACT FROM PUBLISHER]

Published

2015

174. DC-to-DC Converter With Low Input Current Ripple for Maximum Photovoltaic Power Extraction.

Author

El Khateb, Ahmad H., Rahim, Nasrudin Abd, Selvaraj, Jeyraj, and Williams, Barry W.

Subjects

DC-to-DC converters, MAXIMUM power point trackers, ELECTRIC power conversion, ELECTRIC current converters, PHOTOVOLTAIC power systems, PHOTOVOLTAIC cells, SWITCHING power supplies

Abstract

This paper presents a dc-to-dc converter, which offers continuous input and output energy flow and low input current ripple, applicable and mandatory for photovoltaic (PV) arrays and maximum power tracking applications. The PV array yields exponential curves for current and voltage where maximum power occurs at the curve's mutual knee. Conventional dc-to-dc converters have a relatively high input current ripple which causes high power losses when connected to nonlinear sources like PV arrays. The proposed converter maximizes the power that can be sourced from the PV array, without the need of any electrolytic filtering capacitance. The effect of current ripple can be significant and decreases PV system efficiency. Converter simulations and experimental results support and extol the system concept. [ABSTRACT FROM PUBLISHER]

Published

2015

175. Circulating Current Injection Methods Based on Instantaneous Information for the Modular Multilevel Converter.

Author

Pou, Josep, Ceballos, Salvador, Konstantinou, Georgios, Agelidis, Vassilios G., Picas, Ricard, and Zaragoza, Jordi

Subjects

CONVERTERS (Electronics), AMPLITUDE modulation, CAPACITORS, ELECTRIC potential, ELECTRIC currents

Abstract

This paper studies different circulating current references for the modular multilevel converter. The circulating current references are obtained from the instantaneous values of the output current and modulation signal of the phase leg. Therefore, the determination of the amplitude and phase of the output current is not needed, which is a significant improvement compared to other methods such as those based on injecting specific harmonics in the circulating currents. Among the different methods studied in this paper, a new method is introduced, which is able to reduce the capacitor voltage ripples compared to the other methods. A closed-loop control is also proposed which is able to track the circulating current references. With the discussed methods, the average values of the capacitor voltages are maintained at their reference while the voltage ripples are kept low. Experimental results are presented to demonstrate the effectiveness of the proposed and discussed methods. [ABSTRACT FROM PUBLISHER]

Published

2015

176. Capacitance Reduction With An Optimized Converter Connection Applied to LED Drivers.

Author

Camponogara, Douglas, Vargas, Diogo Ribeiro, Dalla Costa, Marco Antonio, Alonso, J. Marcos, Garcia, Jorge, and Marchesan, Tiago

Subjects

AC DC transformers, ELECTRIC transformers, LIGHT emitting diodes, CASCADE converters, ENERGY consumption research

Abstract

This paper presents a new control method and a detailed project methodology for the optimized connection method of two converters, aiming to reduce the redundant power processing, in order to supply high-power light-emitting diodes (LEDs) with reduced capacitance and high efficiency, directly from the ac line. This connection method allows dealing with two major issues related to the LED driver: capacitance reduction and efficiency increasing. The first converter provides power factor correction, whereas the second converter controls the current through the LED. The basic idea consists in making the second converter to process only the low-frequency ripple (LFR) of the first converter, thus smoothing the LED current. In this way, the LFR is managed by the second stage, so that the capacitance of the first stage can be significantly reduced. The proposed control method can achieve better results for the low-frequency compensation. In addition to that, a high power factor and a low harmonic content are obtained, fulfilling the IEC 61000-3-2 Class C requirements. A laboratory prototype with a rated power of 75 W and an input voltage of 220 \Vrms/60 Hz was built in order to show the feasibility of the idea. The measured overall efficiency of the converter was 91%, and electrolytic capacitors were avoided. [ABSTRACT FROM PUBLISHER]

Published

2015

177. Nonisolated High Step-Up DC–DC Converters Adopting Switched-Capacitor Cell.

Author

Wu, Gang, Ruan, Xinbo, and Ye, Zhihong

Subjects

CASCADE converters, ELECTRIC current converters, CAPACITOR switching, HIGH voltages, ELECTRIC power systems research, PHOTOVOLTAIC cells, FUEL cells

Abstract

In a photovoltaic (PV)- or fuel-cell-based grid-connected power system, a high step-up dc–dc converter is required to boost the low voltage of a PV or fuel cell to a relatively high bus voltage for the downstream dc–ac grid-connected inverter. To integrate the advantages of the high voltage gain of a switched-capacitor (SC) converter and excellent output regulation of a switching-mode dc–dc converter, a method of combining the two types of converters is proposed in this paper. The basic idea is that when the switch is turned on, the inductor is charged, and the capacitors are connected in series to supply the load, and when the switch is turned off, the inductor releases energy to charge multiple capacitors in parallel, whose voltages are controlled by a pulsewidth modulation technique. Thus, a high voltage gain of the dc–dc converter can be obtained with good regulation. Based on this principle, a series of new topologies are derived, and the operating principles and voltage gains of the proposed converters are analyzed. Finally, the design of the proposed converter is given, and the experiment results are provided to verify the theoretical analysis. [ABSTRACT FROM PUBLISHER]

Published

2015

178. Filter Design of Direct Matrix Converter for Synchronous Applications.

Author

Dasgupta, Anindya and Sensarma, Parthasarathi

Subjects

CASCADE converters, ELECTRIC loss in electric power systems, ELECTRIC potential, ELECTRIC currents, ELECTRIC power filters

Abstract

Filters for switching ripple attenuation are essential at the input, and sometimes at the output for certain applications, for the deployment of matrix converters (MCs). Due to the absence of inertial elements in the MC structure and the consequent tight input–output coupling, the filter parameters significantly affect its dynamic behavior. This paper presents an exhaustive filter design method for synchronous applications of the MC in power systems. Apart from the usual considerations of ripple attenuation, voltage regulation, reactive current loading, and internal losses, this paper also addresses additional constraints which may be imposed by requirements of dynamic performance and reliable commutation. Rigorous analytical justification of each design step is provided and the sequential design process is summarized. Relevant experimental results are presented to validate the proposed design tool. [ABSTRACT FROM PUBLISHER]

Published

2014

179. 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

180. Hybrid Multilevel Inverter Using Switched Capacitor Units.

Author

Babaei, Ebrahim and Gowgani, Saeed Sheermohammadzadeh

Subjects

ELECTRIC inverters, CAPACITORS, TOPOLOGY, ENERGY storage, ELECTRIC equipment

Abstract

In this paper, two new topologies are proposed for multilevel inverters. The proposed topologies consist of a combination of the conventional series and the switched capacitor inverter units. The proposed topologies reduce the number of switches and isolated dc voltage sources, the variety of the dc voltage source values, and the size and cost of the system in comparison with the conventional topologies. In addition, the proposed topologies can double the input voltage without a transformer. There is no need for complicated methods to balance the capacitor voltage. The simulation and experimental results of single-phase 25- and 17-level inverters are given to prove the correct operation of the proposed topologies. [ABSTRACT FROM PUBLISHER]

Published

2014

181. Delta-Channel Modular Multilevel Converter for a Variable-Speed Motor Drive Application.

Author

Du, Sixing, Wu, Bin, and Zargari, Navid

Subjects

VARIABLE speed drives, MOTOR drives (Electric motors), ELECTRIC power conversion, CONVERTERS (Electronics), COMPUTER algorithms

Abstract

Delta-channel modular multilevel converter (MMC) proved successful for zero/low-fundamental-frequency operation without injecting common-mode voltage. However, its application in a medium-voltage variable-speed motor drive is not verified. This paper develops a variable-speed motor drive system based on a delta-channel MMC. The converter power losses together with the compensation strategies are analyzed, and accordingly the submodule capacitor voltage controls are elaborated. The converter controls cascaded with the advanced motor control form the entire control scheme for the drive system. The system performances are tested based on a 4160-V 1-MW simulation model and 208-V 5-kW experimental setup. The results show that the delta-channel MMC along with the proposed control algorithm performs satisfactorily in a driving motor from standstill to a rated speed even under rated torque condition. [ABSTRACT FROM PUBLISHER]

Published

2018

182. An Integrated Concurrent Multiple-Input Self-Startup Energy Harvesting Capacitive-Based DC Adder Combiner.

Author

Abouzied, Mohamed A., Osman, Hatem, Vaidya, Vaibhav, Ravichandran, Krishnan, and Sanchez-Sinencio, Edgar

Subjects

ENERGY harvesting, CAPACITIVE sensors, DIRECT currents, ELECTRIC potential, SOLAR cells

Abstract

This paper introduces a switched-capacitor dc combiner suitable for energy harvesting applications. Since the dc voltage is small, addition of the voltages from different sources can boost the final output voltage with self-startup capability. This approach is valid for any number of dc voltage sources. To prove the energy harvesting principle, three sources are selected. The design of the three-input dc combiner, with no closed-loop controller, is fabricated in 0.13-\mu\textm CMOS technology and the chip area is 1.5 × 1.5 \textmm^2. With integrated tunable thyristor-based differential oscillators, the chip can combine power from all three inputs. Manual frequency modulation is used to deliver the maximum power to the load. The system has proven to be functional even if one or two of the sources is/are weak or not available. Finally, for indoor conditions, the power from three different solar cells is combined where 70 $\mu$ W is harvested with an open-circuit voltage of 1.4 V and the short-circuit current of 160 $\mu$A. [ABSTRACT FROM PUBLISHER]

Published

2018

183. Flexible Control of Photovoltaic Grid-Connected Cascaded H-Bridge Converters During Unbalanced Voltage Sags.

Author

Tafti, Hossein Dehghani, Maswood, Ali Iftekhar, Konstantinou, Georgios, Townsend, Christopher David, Acuna, Pablo, and Pou, Josep

Subjects

PHOTOVOLTAIC power generation, ELECTRIC potential, CONVERTERS (Electronics), ELECTRIC power conversion, CAPACITORS

Abstract

Multilevel cascade H-bridge (CHB) converters are one of the promising solutions for medium- and large-scale grid-connected photovoltaic power plants. However, there is a lack of a complete study about their operation during voltage sags. This paper proposes a flexible control strategy for the operation of photovoltaic grid-connected CHB inverters during unbalanced voltage sags. The key novelty is that the proposed strategy is able to inject both active and reactive powers to the grid with either balanced or unbalanced currents, while ensuring that all dc-link capacitor voltages remain balanced. The simulation and experimental evaluations of a 9-kVA grid-connected seven-level CHB illustrate and validate the performance of the proposed strategy for the operation of the grid-connected CHB converter during different unbalanced voltage sags. [ABSTRACT FROM PUBLISHER]

Published

2018

184. An Improved DC Solid State Transformer Based on Switched Capacitor and Multiple-Phase-Shift Shoot-Through Modulation for Integration of LVDC Energy Storage System and MVDC Distribution Grid.

Author

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

Subjects

ENERGY storage, DIRECT currents, ELECTRIC transformers, CAPACITORS, TOPOLOGY, ELECTRIC potential

Abstract

This paper proposes an improved dc transformer (NDCT hereinafter) based on switched capacitor with reduced switches for the integration of low-voltage dc energy storage systems and medium-voltage dc power distribution grid. The topology, phase-shift (PS) shoot-through and multiple PS modulations, and voltage, current, and power characterizations, as well as commutation characterization and control strategy, are proposed and analyzed comprehensively. Compared with the traditional schemes, the proposed NDCT not only can enhance reliability and flexibility but can increase voltage adjustment and power transfer capabilities as well. Moreover, the current ripple performance and soft-switching performance are improved, and the number and capacity of switches are reduced, thereby increasing the efficiency and cost of the system. Finally, an NDCT prototype is built. Experimental results verify the correctness and effectively of the proposed solution. [ABSTRACT FROM PUBLISHER]

Published

2018

185. A New Interleaved Coupled-Inductor Nonisolated Soft-Switching Bidirectional DC?DC Converter With High Voltage Gain Ratio.

Author

Bahrami, Hamid, Farhangi, Shahrokh, Iman-Eini, Hossein, and Adib, Ehsan

Subjects

DC-to-DC converters, ELECTRIC inductors, HIGH voltages, LOW voltage integrated circuits, ZERO voltage switching, ELECTRIC current converters, PHASE-shift masks

Abstract

This paper presents a new interleaved coupled-inductor nonisolated bidirectional dc–dc converter that provides high voltage gain ratio (VGR), low ripple current at the low-voltage side (LVS), and soft switching. The high VGR is obtained by connecting in series the outputs of an interleaved bidirectional buck–boost converter and a dual-active half-bridge converter, using the turns ratio of a coupled inductor. Since the voltage of the high-voltage side is shared between the converters outputs, the voltage stress across the active switches decrease. The active switches turn ON under zero-voltage switching condition in both directions. Moreover, the low current ripple at the LVS is achieved due to the applied interleaved technique. By employing the phase-shift angle modulation, the output voltage is regulated. The proposed converter is analyzed in details and a 900-W experimental prototype with 48-V input voltage and 400-V output voltage under 100-kHz switching frequency is implemented to verify the theoretical results. [ABSTRACT FROM PUBLISHER]

Published

2018

186. Transformer-Free, Off-the-Shelf Electrical Interface for Low-Voltage DC Energy Harvesting.

Author

Lallart, Mickael, Phung, Luong Viet, and Massot, Bertrand

Subjects

ENERGY harvesting, ELECTRIC oscillators, DIRECT current machinery, THERMOELECTRIC generators, MICROHARVESTERS (Electronics)

Abstract

Energy harvesting from various ambient energy sources keeps gaining interest to deal with the challenges arising from more and more widespread Internet of Things applications in consumer electronics and industrial applications such as remote sensing. However, available energy is scarce and designers must comply with small size package and thermal dissipation that inevitably lead to compromises. This paper presents a transformer-free and self-powered oscillator that can be directly powered from a very low dc voltage source such as a thermoelectric module and able to deliver dc bias output. Using off-the-shelves parts, such a design is less cumbersome and gives more freedom to designers while tailoring their circuits with respect to their applications. The oscillator consists of a modified Hartley oscillator including a supplementary capacitor that provides a bias voltage in its output. Theoretical analysis is validated through experimental measurements showing that the proposed solution could be deployed in buildings and/or wearable devices as small and cheap complete microgenerators using for example thermoelectric elements or microbial fuel cells. [ABSTRACT FROM PUBLISHER]

Published

2018

187. High Step-Up DC–DC Converter Based on Switched Capacitor and Coupled Inductor.

Author

Wu, Gang, Ruan, Xinbo, and Ye, Zhihong

Subjects

PHOTOVOLTAIC power systems, CAPACITOR switching, CASCADE converters, HIGH voltages, ELECTRIC potential

Abstract

Due to the relatively low output voltage of photovoltaic (PV) source, a high step-up converter with high efficiency is needed when the PV source is connected to the power grid. A novel high step-up converter based on two switched capacitors and a coupled inductor is proposed in this paper. The operating principle is analyzed and the voltage gain is derived. A 100-W prototype is fabricated in the laboratory to verify the theoretical analysis, and the highest efficiency is 96.4%. [ABSTRACT FROM PUBLISHER]

Published

2018

188. A Novel Interleaved Tri-State Boost Converter With Lower Ripple and Improved Dynamic Response.

Author

Rana, Niraj, Kumar, Mukesh, Ghosh, Arnab, and Banerjee, Subrata

Subjects

CONVERTERS (Electronics), DIRECT currents, ELECTRONIC controllers, ELECTRIC potential, ELECTRONIC circuits

Abstract

In this paper, the design and development of a novel interleaved tri-state boost converter (ITBC), which produces lower ripple and exhibits better dynamic response, is discussed. Boost converters are frequently connected in parallel and operate in an interleaving mode for the reduction of ripple content in source current and in output voltage. In this way, interleaved boost converter (IBC) is conceived, which improves the power handling capabilities and increases the overall system rating. It also has the advantage of reduction of the ripple content in source current and output voltage, but when control-to-output transfer function of IBC is derived under continuous conduction mode of operation, then a right-half-plane (RHP) zero appears in the transfer function. Due to the presence of RHP zero, IBC has nonminimum phase problem, which deteriorates the dynamic performance. The tri-state boost converter (TBC) is the best choice for RHP zero elimination, but due to the extra freewheeling mode, ripple content will also be increased. The proposed converter is a parallel combination of two TBC and operates in an interleaving mode. Therefore, the proposed converter has both of the advantages of TBC and IBC. The performance analyses of ITBC, TBC, and IBC have been studied based on simulation and experimental results. From the comparative analysis, it is observed that ITBC is performed better than other two converters. The ripple comparisons between three converters have also been done. It is found that the ripple content in ITBC is slightly greater than IBC but is less than TBC. [ABSTRACT FROM PUBLISHER]

Published

2018

189. Modeling, Design, Control, and Implementation of a Modified Z-Source Integrated PV/Grid/EV DC Charger/Inverter.

Author

Singh, Siddhartha A., Azeez, Najath A., Williamson, Sheldon S., and Carli, Giampaolo

Subjects

ELECTRIC inverter design & construction, SOLAR energy, BATTERY chargers, TOPOLOGY, ELECTRIC vehicle batteries, CAPACITORS, DISTRIBUTED power generation

Abstract

Solar energy has been the most popular source of renewable energy for residential and semicommercial applications. Fluctuations of solar energy harvested due to atmospheric conditions can be mitigated through energy storage systems (ESS). Solar energy can also be used to charge electric vehicle batteries to reduce the dependence on the grid. One of the requirements for a converter for such applications is to have a reduced number of conversion stages and provide isolation. The Z-source inverter (ZSI) topology is able to remove multiple stages and achieve voltage boost and dc–ac power conversion in a single stage. The use of passive components also presents an opportunity to integrate ESS into them. This paper presents modeling, design, and operation of a modified ZSI integrated with a split primary isolated battery charger for dc charging of electric vehicle batteries. Simulation and experimental results have been presented for the proof of concept of the operation of the proposed converter. [ABSTRACT FROM PUBLISHER]

Published

2018

190. Sliding Mode Controller in a Multiloop Framework for a Grid-Connected VSI With LCL Filter.

Author

Vieira, Rodrigo Padilha, Martins, Leandro Tome, Massing, Jorge Rodrigo, and Stefanello, Marcio

Subjects

ELECTRIC controllers, SLIDING mode control, IDEAL sources (Electric circuits), DISCRETE time filters, ELECTRIC inverters, ELECTRIC potential, MATHEMATICAL models

Abstract

This paper proposes a multiloop framework for current control of grid-connected voltage source inverters (VSIs) with LCL output filter. The discrete-time model is of third-order with a nonminimum phase zero when controlling the grid side current. This poses some difficulties on the design of most types of controllers. Motivated by this problem, the inner loop is implemented by a discrete-time sliding mode control law to ensure the tracking of the converter side current. This can be achieved regardless the grid impedance and voltage, making the converter to behave like a current source inverter with a capacitive+inductive (CL) filter. Thus, the problem of current control falls from a third-order system to a second-order system. Several types of controllers can be designed to implement the outer loop based on the equivalent CL circuit. In this work, a resonant controller with a virtual resistor was applied. Simulations and experimental results are presented to validate the proposal. [ABSTRACT FROM PUBLISHER]

Published

2018

191. Analysis and Design of a Family of Two-Level PWM Plus Phase-Shift-Modulated DC?DC Converters.

Author

Li, Shouxiang, Smedley, Keyue Ma, and Xiangli, Kang

Subjects

DC-to-DC converters -- Design & construction, PULSE width modulation transformers, PHASE shifters, ELECTRIC controllers, ZERO voltage switching, LEAKAGE inductance

Abstract

A comprehensive analysis for a family of two-level pulsewidth modulation plus phase-shift (PPS)-modulated-isolated-bidirectional dc–dc converters is presented in this paper. Compared with the traditional phase-shift control, the PPS control features reduced current stresses, reduced conduction losses, guaranteed zero-voltage switching (ZVS) operation, and wide conversion-ratio variation range. In this paper, all eight operation modes are revealed, and then the unified solution of the power transmission capability for each mode is proposed, applicable for any two-level PPS converters. Based on the unified solution, component stresses and ZVS operation are analyzed to assist component selection. Most importantly, the control maps for three different combinations of the two-level PPS converters are proposed, to assist converter operation and design in the low-circulating-current region. In the control map, a circuit parameter k is proposed and its upper limit is found, providing a design limit to select switching frequency, leakage inductance, turns ratio, and power level. A 29–67 V/380 V prototype—the combination of group C plus group A—rated at 100–1000 W was built. The analysis is verified by both simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

192. Analysis of a New Single-Stage Soft-Switching Power-Factor-Correction LED Driver With Low DC-Bus Voltage.

Author

Khalilian, Hosein, Farzanehfard, Hosein, Adib, Ehsan, and Esteki, Morteza

Subjects

LIGHT emitting diodes, ELECTRIC power factor correction, SWITCHING circuits, DIGITAL electronics, ELECTRONIC circuits

Abstract

A new isolated single-stage soft-switching power-factor-correction (S4 PFC) driver for supplying light-emitting diodes (LEDs) is introduced in this paper. In the proposed LED driver, the switches voltage stress and also the dc-bus voltage is limited to the peak of the line voltage. Hence, low voltage rated mosfets and diodes can be used. The efficiency is improved because the switches are turned on under zero current switching (ZCS) condition and turned off under zero voltage zero current switching (ZVZCS) condition. Also, no current feedback is required since the converter provides an output current independent of output voltage. In this paper, operating principle of the proposed LED driver is presented and design considerations are discussed. To verify the theoretical analysis, a laboratory prototype of the proposed converter for supplying a 50 W/70 V LED module from 220 Vrms/50 Hz ac mains is implemented, and the experimental results are presented. Since current feedback is not used, dimming property and operation for universal voltage range is not achievable. [ABSTRACT FROM PUBLISHER]

Published

2018

193. Finite-Set Model-Predictive Control Strategies for a 3L-NPC Inverter Operating With Fixed Switching Frequency.

Author

Donoso, Felipe, Mora, Andres, Cardenas, Roberto, Angulo, Alejandro, Saez, Doris, and Rivera, Marco

Subjects

ELECTRIC inverters, CLAMPING circuits, PREDICTIVE control systems, ELECTRIC current converters, ELECTRONIC circuits

Abstract

In this paper, finite-set model-predictive control (FS-MPC) methodologies for a grid-connected three-level neutral-point-clamped converter are investigated. The proposed control strategies produce fixed switching frequency, maintaining all the advantages of predictive control such as fast dynamic response, inclusion of nonlinearities and restrictions, and multivariable control using a single control loop. The first of the proposed FS-MPC strategies is based on a multiobjective cost function, designed to regulate both the inverter currents and the balancing of the dc-link capacitor voltages. The second FS-MPC strategy is derived from the first one, and it is based on a cost function that regulates only the grid current, with the balancing of the capacitor voltages being realized by controlling the duty cycles of the redundant vectors. The proposed control systems are experimentally validated using a 5-kW prototype. The experimental results show a good performance for both strategies, in steady-state and transient response, with a total harmonic distortion lower than \text2\% for the currents supplied to the grid. [ABSTRACT FROM PUBLISHER]

Published

2018

194. Single-Stage Integrated Bridgeless-Boost Nonresonant Half-Bridge Converter for LED Driver Applications.

Author

Malschitzky, Alessandro, Albuquerque, Felipe, Agostini, Eloi, and Nascimento, Claudinor Bitencourt

Subjects

LIGHTING, ELECTRIC power factor, LIGHT emitting diodes, CONVERTERS (Electronics), ELECTRIC power conversion

Abstract

A nonisolated single-stage electronic lighting system with a high power factor for driving power light-emitting diodes (LEDs) is proposed in this paper. The presented topology is based on the integration of a bridgeless boost rectifier with a nonresonant half-bridge converter. Accurate steady-state analyses of the nonresonant- and resonant-based circuits are reported, serving as the basis for designing the lighting systems. The LEDs current is adjusted by means of frequency modulation, being the converter switches driven by complementary symmetrical signals. A small-signal analysis is detailed for the proposed nonresonant scheme, providing fundamental information regarding its dynamic behavior. Also, a step-by-step design procedure based on the performed mathematical analysis is elaborated, allowing the adequate design of the proposed lighting system. In order to confirm the validity and the feasibility of the proposed converter, experimental results for a 42-W, 127- \rmV{\rm{rms}}, 50-kHz, 94.2% peak efficiency prototype are presented. [ABSTRACT FROM PUBLISHER]

Published

2018

195. Integrated Half-Bridge CLLC Bidirectional Converter for Energy Storage Systems.

Author

Zhang, Chunjiang, Li, Pengcheng, Kan, Zhizhong, Chai, Xiuhui, and Guo, Xiaoqiang

Subjects

CONVERTERS (Electronics), DIRECT currents, VOLTAGE-frequency converters, PULSE width modulation transformers, ZERO current switching, ZERO voltage switching

Abstract

This paper proposes an integrated half-bridge CLLC (IHBCLLC) resonant bidirectional dc–dc converter suitable as an interface between two dc voltage buses in various applications including energy storage systems. This converter is an integration of a half-bridge CLLC resonant circuit and a buck/boost circuit. Compared with the traditional pulse frequency modulation and phase-shift controlled CLLC resonant converter, for the proposed convertor, the high voltage gain can be obtained from pulse width modulation. Synchronous pulse width modulation is adopted for the converter, and the switching frequency is equal to the resonant frequency. The CLLC resonant circuit can help MOSFETs to achieve soft switching and high voltage gain. The simulation analysis of the modulation schedule and operating principle of the proposed converter prove that the converter is able to achieve zero-voltage switching or zero-current switching. Experimental results obtained from a 1-kW converter prototype confirm the theoretical analysis and the simulation results. [ABSTRACT FROM PUBLISHER]

Published

2018

196. ESI: A Novel Three-Phase Inverter With Leakage Current Attenuation for Transformerless PV Systems.

Author

Guo, Xiaoqiang, Yang, Yong, and Zhu, Tieying

Subjects

ELECTRIC inverters, PHOTOVOLTAIC power generation, ELECTRIC potential, CONVERTERS (Electronics), NUMERICAL analysis

Abstract

Adding the auxiliary switches to the conventional H-bridge inverter is an effective way to eliminate the leakage current for transformerless PV systems, such as H5, H6, etc. Inspired by the newly developed embedded-switch H6 topology, a novel embedded-switch inverter (ESI) is proposed in this paper for three-phase transformerless PV systems. First, the operation principle and characteristics of the proposed ESI are analyzed. Second, the common-mode model of the three-phase ESI is established, based on which the main factors that affect the leakage current are discussed. The finding reveals that the switching states with conventional modulation strategy result in high-frequency common-mode voltage, which is the source of leakage current. In order to solve the problem, a new modulation strategy is presented for ESI to eliminate the high-frequency leakage current. Finally, the time-domain simulation and the experimental tests are carried out. The results verify the effectiveness of the proposed solution. [ABSTRACT FROM AUTHOR]

Published

2018

197. Current-Dependent Capacitor Voltage Control of Parallel Autonomous UPS Systems.

Author

Shamseh, Mohammad Bani, Yoshino, Teruo, and Kawamura, Atsuo

Subjects

ELECTRIC potential, UNINTERRUPTIBLE power supply, ELECTRIC inverters, POWER resources, POWER electronics

Abstract

This paper proposes a novel autonomous control scheme for equal load current distribution between $n$ parallel-connected, LCL-based, three-phase online uninterruptible power supply (UPS) modules. The control is based on regulating the reference voltage of the filter's capacitor of each inverter as a function of its own output current. The control is achieved without exchanging information between the inverters. The load voltage is maintained fixed at the specified reference value. The control method is fast, precise, and robust against load variations. The validity of the proposed method is verified experimentally and by simulation on a system of two parallel inverters under different load conditions, including step-load and nonlinear load. [ABSTRACT FROM AUTHOR]

Published

2018

198. Direct Instantaneous Ripple Power Predictive Control for Active Ripple Decoupling of Single-Phase Inverter.

Author

Ge, Baoming, Li, Xiao, Zhang, Haiyu, Liu, Yushan, Balog, Robert S., Abu-Rub, Haitham, and Alpuerto, Lance

Subjects

ELECTRIC inverters, AUTOMATIC control systems, ELECTRIC potential, ELECTRIC circuits, CAPACITORS

Abstract

Active ripple decoupling technique of the single-phase inverter is a popular topic to minimize the dc-link capacitance. However, the existing control methods are based on tracking sinusoidal or predetermined voltage waveforms of the compensation capacitor, assuming the inverter outputs are pure sinusoidal voltage and current. Therefore, the performance of existing methods degrades when the inverter output voltage and current are not purely sinusoidal. Furthermore, the limited dynamic performance threatens the safety of dc-link capacitor when the load changes. This happens, because the inrush ripple power is injected into dc link with small capacitance and the dc-link voltage will suddenly rise up when the ripple power is not buffered during transients. In this paper, a direct instantaneous power predictive control is proposed for the decoupling circuit to buffer ripple power of the single-phase inverter, which combines instantaneous ripple power control with model predictive control to overcome the issues above. The proposed method tracks the instantaneous ripple power rather than voltage or current waveforms. In this way, it can fully buffer all ripple powers in the system even for distorted output voltage and current of the inverter and enables the full utilization of storage capacitor. In addition, model predictive control makes the proposed method have fast dynamic and perfectly compensate ripple power during transients and steady states. The buck-type active ripple decoupling circuit is chosen to implement the proposed method after comparing with another typical decoupling topology. The proposed method is also compared with conventional method using proportional-integral-resonant regulator to track the predetermined capacitor voltage waveform. Experimental tests verify the theoretical analysis and the proposed control method. [ABSTRACT FROM AUTHOR]

Published

2018

199. Common-Ground-Type Transformerless Inverters for Single-Phase Solar Photovoltaic Systems.

Author

Siwakoti, Yam P. and Blaabjerg, Frede

Subjects

CAPACITORS, ELECTRIC inverters, PHOTOVOLTAIC power systems, BIPOLAR transistors, ELECTRIC network topology

Abstract

This paper proposes a family of novel flying capacitor transformerless inverters for single-phase photovoltaic (PV) systems. Each of the new topologies proposed is based on a flying capacitor principle and requires only four power switches and/or diodes, one capacitor, and a small filter at the output stage. A simple unipolar sinusoidal pulse width modulation technique is used to modulate the inverter to minimize the switching loss, output current ripple, and the filter requirements. In general, the main advantages of the new inverter topologies are: 1) the negative polarity of the PV is directly connected to the grid, and therefore, no leakage current; 2) reactive power compensation capability; and 3) the output ac voltage peak is equal to the input dc voltage (unlike neutral-point-clamped and derivative topologies, which requires twice the magnitude of the peak ac voltage). A complete description of the operating principle with modulation techniques, design guidelines, and comprehensive comparisons is presented to reveal the properties and limitations of each topology in detail. Finally, experimental results of 1-kVA prototypes are presented to prove the concept and theoretical analysis of the proposed inverter family for practical applications. [ABSTRACT FROM PUBLISHER]

Published

2018

200. Soft-Switching High Static Gain DC–DC Converter Without Auxiliary Switches.

Author

Meier, Martin Breus, Avelino da Silva, S., Badin, Alceu Andre, Gules, Roger, and Romaneli, Eduardo Felix Ribeiro

Subjects

ELECTRIC power conversion, DC-to-DC converters, VOLTAGE multipliers, STATIC relays, ZERO current switching, ZERO voltage switching

Abstract

The development of a high static gain dc–dc converter with the integration of the voltage multiplier cell and the coupled inductors operating with soft switching is presented in this paper. The use of coupled inductors and voltage multiplier techniques allow the operation with low switch voltage and low conduction losses. The switch turn-on commutation occurs with zero current switching due to the presence of the coupled-inductor leakage inductance. The leakage inductance also reduces the reverse recovery current of all diodes. The zero voltage switching at the power switch turn-off is obtained with the inclusion of only a diode and a snubber capacitor per phase, without the use of auxiliary switches. The soft-switching range is independent of the load and is maintained even with a light load. The theoretical analysis, design procedure, and experimental results are presented in this paper. A two-phase boost converter with one voltage multiplier and coupling inductors was built with an input voltage $V_{{\text{in}}}= { \text{24 V}}, output voltage Vo= { \text{432 V}}, and output power Po= { \text{400 W}}. The efficiency obtained is equal to 94.55% at the nominal power. [ABSTRACT FROM PUBLISHER]

Published

2018