Showing total 274 results

51. Capacitance Reduction of the Hybrid Modular Multilevel Converter by Decreasing Average Capacitor Voltage in Variable-Speed Drives.

Author

Zhou, Shaoze, Li, Binbin, Guan, Mingxu, Zhang, Xinyi, Xu, Zigao, and Xu, Dianguo

Subjects

*ELECTRIC capacity, *CASCADE converters, *CAPACITORS, *VARIABLE speed drives, *PULSE width modulation

Abstract

Modular multilevel converters (MMCs) represent an emerging topology in medium-voltage (MV) and high-voltage applications. But for MV variable-speed motor drives, the MMC faces the challenge of large capacitor voltage ripple at low speeds. Delightfully, a hybrid MMC (HMMC) has proved to be potential in MV motor drives, since this topology has a lower capacitor voltage ripple and does not introduce any common voltage to the motor. This paper proposed a method to decrease the average capacitor voltage of the HMMC, which can effectively drive the motor at very low speeds without significantly increasing the submodule (SM) capacitance. Moreover, the selection of average capacitor voltage and the dimension of the SM capacitance are presented. Simulation and experimental results verify the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

52. Closed-Loop Design and Transient-Mode Control for a Series-Capacitor Buck Converter.

Author

Kirshenboim, Or, Vekslender, Timur, and Peretz, Mor Mordechai

Subjects

*CAPACITORS, *CLOSED loop systems, *ELECTRIC transients, *CASCADE converters, *VOLTAGE control, *VOLTAGE regulators

Abstract

This paper explores the large-signal and small-signal dynamics of a series-capacitor (SC) buck-type converter and introduces an optimal closed-loop control scheme to accommodate both the steady-state and transient modes. As opposed to a conventional buck converter, where time-optimal control is realized by a single on–off cycle, in the SC-buck topology, there is a need to distribute the switching phases to satisfy the charge balance of the SC. The new control method merges a voltage-mode controller for the steady-state operation and a nonlinear, state-plane based transient-mode controller for load transients. A detailed principle of the operation of the SC-buck converter is provided and explained through an average-behavioral model and state-plane analysis. The operation of the controller is experimentally verified on a 20 W 12 V-to-1 V converter, demonstrating voltage-mode control operation as well as minimum-deviation and time-optimal responses for load transients. [ABSTRACT FROM AUTHOR]

Published

2019

53. Three-Phase Single-Stage-Isolated Cuk-Based PFC Converter.

Author

Gangavarapu, Sivanagaraju, Rathore, Akshay Kumar, and Fulwani, Deepak M.

Subjects

*ELECTRIC power factor, *CASCADE converters, *VOLTAGE control, *HARMONIC distortion (Physics), *MATHEMATICAL analysis

Abstract

In this paper, analysis and design of a three-phase-isolated Cuk-based power factor correction (PFC) converter have been proposed. The proposed converter is operated in discontinuous output inductor current mode to achieve PFC at ac input. This avoids the inner current control loop which further eliminates the sensing of current. This makes the system more reliable and robust. The converter requires only one simple voltage control loop for output voltage regulation, and all the power switches are driven by the same gate signal which simplifies the gate driver circuit. The detailed operation of the converter and design calculations are presented. And also a small-signal model of the converter by using current injected equivalent circuit approach is presented to aid the controller design. The experimental results from a 2-kW laboratory prototype with 208-V line-to-line input voltage, 400-V output voltage are presented to confirm the operation of the proposed converter. An input power factor of 0.999, an input current total harmonic distortion of as low as 4.06%, and a high conversion efficiency of 95.1% are achieved from laboratory prototype. [ABSTRACT FROM AUTHOR]

Published

2019

54. Switched-Capacitor-Based Single-Source Cascaded H-Bridge Multilevel Inverter Featuring Boosting Ability.

Author

Khoun Jahan, Hossein, Abapour, Mehdi, and Zare, Kazem

Subjects

*CAPACITOR switching, *CASCADE converters, *ELECTRIC inverters, *HARMONIC distortion (Physics), *PHOTOVOLTAIC power systems

Abstract

Cascaded multilevel inverter (CMI) is one of the most popular multilevel inverter topologies. This topology is synthesized with some series-connected identical H-bridge cells. CMI requires several isolated dc sources which brings about some difficulties when dealing with this type of inverter. This paper addresses the problem by proposing a switched-capacitor (SC)-based CMI. The proposed topology, which is referred to as switched-capacitor single-source CMI (SCSS-CMI), makes use of some capacitors instead of the dc sources. Hence, it requires only one dc source to charge the employed capacitors. Usually, the capacitor charging process in a SC cell is companied by some current spikes which extremely harm the charging switch and the capacitor. The capacitors in SCSS-CMI are charged through a simple auxiliary circuit which eradicates the mentioned current spikes and provides zero-current switching condition for the charging switch. A computer-aid simulated model along with a laboratory-built prototype is adopted to assess the performances of SCSS-CMI, under different conditions. [ABSTRACT FROM AUTHOR]

Published

2019

55. Switching-Cell Arrays—An Alternative Design Approach in Power Conversion.

Author

Busquets-Monge, Sergio and Caballero, Luis

Subjects

*ENERGY conversion, *CASCADE converters, *IDEAL sources (Electric circuits), *SEMICONDUCTOR diodes, *CAPACITORS

Abstract

The conventional design of voltage-source power converters is based on a two-level half-bridge configuration and the selection of power devices designed to meet the full application specifications (voltage, current, etc.). This leads to the need to design and optimize a large number of different devices and their ancillary circuitry and prevents taking advantage from scale economies. This paper proposes a paradigm shift in the design of power converters through the use of a novel configurable device consisting on a matrix arrangement of highly optimized switching cells at a single voltage class. Each switching cell consists of a controlled switch with antiparallel diode together with a self-powered gate driver. By properly interconnecting the switching cells, the switching-cell array (SCA) can be configured as a multilevel active-clamped leg with a different number of levels. Thus, the SCA presents adjustable voltage and current ratings, according to the selected configuration. For maximum compactness, the SCA can be conceived to be only configurable by the device manufacturer upon the customer needs. For minimum cost, it can also be conceived to be configurable by the customer, leading to field-configurable SCAs. Experimental results of a 6 × 3 field-configurable SCA are provided to illustrate and validate this design approach. [ABSTRACT FROM AUTHOR]

Published

2019

56. High-Efficiency Single-Stage LLC Resonant Converter for Wide-Input-Voltage Range.

Author

Kim, Chong-Eun, Baek, Jae-Il, and Lee, Jae-Bum

Subjects

*CASCADE converters, *ELECTRIC potential, *ELECTRIC transformers, *LAPTOP computers, *CAPACITORS, *MAGNETIC resonance

Abstract

In this paper, a new single-stage half-bridge (HB) resonant $LLC$ converter additionally employing one resonant capacitor and two relays with one package is proposed, compared with a single-stage HB $LLC$ converter. Moreover, a center-tapped transformer is replaced with a coupled transformer. Since the proposed converter changes the turns ratio of the coupled transformer using a relay according to low- or high-input-voltage range, it can decrease the range of its needed voltage gain. It means that the proposed converter can be designed with large transformer magnetizing inductance compared with the conventional single-stage HB $LLC$ converter. As a result, the primary conduction and turn-off losses are reduced. Moreover, in low input voltage range, it has smaller total primary wire resistance of the transformer due to parallel connection of the coupled transformer, which decreases its conduction loss. In addition, additionally employed small-sized components can be inserted to the conventional system. To confirm the operation, features, and validity of the proposed converter, universal input with low line and high line and 16.5 V/60 W output laboratory prototype targeting laptop adapters with wide-input-voltage range is built and tested. [ABSTRACT FROM AUTHOR]

Published

2018

57. Introducing Self-Oscillating Technique for a Soft-Switched LED Driver.

Author

Tehrani, Behrooz Mazaheri, Chamali, Masoud Arabi, Adib, Ehsan, Amini, Mohammad Reza, and Najafabadi, Davood Ghayoor

Subjects

*LIGHT emitting diodes, *OSCILLATIONS, *CONVERTERS (Electronics), *ELECTRIC power conversion, *PROTOTYPES, *CASCADE converters

Abstract

In this paper, a self-oscillating soft-switched converter for light-emitting-diode (LED) driver application is presented. In the proposed converter, the self-oscillation conditions are provided with a low number of additional components, and this converter provides a zero-current switching (ZCS) condition for instant switch turn-OFF. This converter does not need additional output current feedback because the output current changes only 10% when the output voltage changes by 33%. The self-oscillating part of this converter applies three low-power BJT and guarantees a soft-switching condition. The proposed self-oscillating control circuit can be implemented with a low cost since it does not need any IC and power supply for the control circuit. The proposed self-oscillating circuit detects the proper moment to turn the switch OFF under the ZCS condition. In order to justify the validity of theoretical analysis, the results of the implemented prototype for driving an LED string are presented. The measured power factor of the prototype shows that, although the input current of the converter is not sinusoidal, this converter can meet the IEC61000-3-2 standard at an operating power of less than 25 W, in addition to having a simple structure and achieving the robust ZCS condition. [ABSTRACT FROM PUBLISHER]

Published

2018

58. Improvement of Power-Conversion Efficiency of AC–DC Boost Converter Using 1:1 Transformer.

Author

Ham, Seok-Hyeong, Choe, Hyung-Jin, Lee, Hyeon-Seok, and Kang, Bongkoo

Subjects

*ELECTRIC power conversion, *CASCADE converters, *ELECTRIC transformers, *ELECTRIC conductivity, *ELECTRIC potential

Abstract

This paper proposes a circuit structure that can improve the power-conversion efficiency \eta e of an AC–DC boost converter. The circuit uses a 1:1 transformer and a voltage boost circuit composed of an inductor, a capacitor, and a diode. The transformer forces the converter to operate in continuous conduction mode for input current, and thereby reduces input ripple. The voltage boost circuit enables the switch to operate in critical conduction mode, so the power loss due to turn-on of switch and reverse recovery of diode is minimized. The proposed converter has high \eta e over a wide range of AC input voltage $V_{{\rm{ac}}}:\,\eta _{e}= 92.9\% $ at $V_{{\rm{ac}}}= {\text{85}}\,{\text{V}} and \eta e= 97.4\% at V{\rm{ac}}= {\text{265}}\,{\text{V}}, when the converter was operated at DC output voltage of 400 V and output power of 500 W. The temperature of the switch stabilized at ∼84 °C for $V_{{\rm{ac}}}= {\text{85}}\,{\text{V}}$ , at ∼70 °C for $V_{{\rm{ac}}}= {\text{110}}\,{\text{V}}$, and at ∼42 °C for $V_{{\rm{ac}}}= {\text{220}}\,{\text{V}}$, whereas that in other AC–DC converters either failed or stabilized at much higher levels. The proposed converter is well suited to systems that require an input voltage range of 85–265 V in root-mean-square value. [ABSTRACT FROM AUTHOR]

Published

2018

59. A Hybrid Resonant ZVZCS Three-Level Converter for MVDC-Connected Offshore Wind Power Collection Systems.

Author

Ning, Guangfu, Chen, Wu, Shu, Liangcai, Zhao, Jianfeng, Cao, Wu, Mei, Jun, Liu, Chun, and Qiao, Guangyao

Subjects

*CASCADE converters, *WIND power, *ELECTRIC filters, *OFFSHORE wind power plants, *BIPOLAR transistors, *ELECTRIC current rectifiers

Abstract

A novel hybrid resonant zero-voltage zero-current switching three-level converter with capacitive output filter is proposed in this paper, which undergoes half of the input voltage for switches and is suitable for offshore wind farms in medium-voltage dc (MVDC) collection systems. The proposed converter, utilizing two transformers with very different power ratings, adopts insulated-gate bipolar transistors for all six power switches and operates in discontinuous current mode and can achieve zero-current switching for the four main switches and rectifier diodes over the whole load range. Meanwhile, the auxiliary switches with small current rating can realize zero-voltage switching naturally. Hence, the switching loss is reduced, which is vital in MVDC applications. By the trajectory formulas of the resonant current and voltage, the trajectory paths can be achieved, which is helpful to compare the peak and turn-off currents of switches. The design rules of main parameters can be deduced with the trajectory formulas and paths. The influence of the turns ratio of auxiliary transformer and the resonant capacitance on the peak and turn-off currents is discussed in detail. The operation principles of the proposed converter are analyzed and verified by the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2018

60. Seamless Fault-Tolerant Operation of a Modular Multilevel Converter With Switch Open-Circuit Fault Diagnosis in a Distributed Control Architecture.

Author

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

Subjects

*CASCADE converters, *OPEN-circuit voltage, *RELIABILITY in engineering, *REDUNDANCY in engineering, *FAULT tolerance (Engineering), *VOLTAGE control

Abstract

Modularity and high reliability from redundancy are the two attractive advantages of modular multilevel converters (MMCs). This paper elaborates a switch open-circuit fault diagnosis and a fault-tolerant operation scheme for MMCs with distributed control. The proposed fault diagnosis and fault-tolerant control method can significantly improve the reliability of the MMC while maintaining the modularity of its software implementation. By distributing fault diagnosis into submodules, its local controller is capable of identifying the switching devices in open-circuit fault without extra hardware circuitry. Based on the real-time measurements of submodule terminal voltage and arm current, single, or multiple faulty switches can be identified within 3.5 ms without triggering faulty alarms. Furthermore, a new fault-tolerant operation is proposed to maintain the output current, internal dynamics, and switching harmonics unchanged after the faulty submodule is bypassed. This is achieved by resetting the period and phase registers in the local controller according to the information of bypassed submodules. The control loops of the MMC are not influenced by the proposed fault diagnosis and fault-tolerant operation, making the operation transition seamless and reliable. Experimental results show that fault identification and system reconfiguration can be completed within 5 ms, and the MMC can seamlessly and smooth ride through the switch open-circuit faults without severe malfunction and catastrophic damages. [ABSTRACT FROM AUTHOR]

Published

2018

61. Active Capacitor Voltage-Balancing Methods Based on the Dynamic Model for a Five-Level Nested Neutral-Point Piloted Converter.

Author

Li, Junjie and Jiang, Jianguo

Subjects

*CAPACITORS, *CASCADE converters, *ELECTRIC potential, *ELECTRIC currents, *HARMONIC distortion (Physics)

Abstract

This paper presents the active capacitor voltage-balancing (ACVB) methods based on the dynamic model for a five-level nested neutral-point piloted (NNPP) converter using hybrid carrier modulation. The traditional hybrid carrier modulation provides natural voltage balancing of floating capacitors and dc-link capacitors. First, the natural voltage-balancing ability under steady-state and ideal conditions is theoretically proved. However, there are accumulated errors and deviations of capacitor voltages in practical applications, especially under dynamic conditions. In order to address the accumulated errors and deviations of capacitor voltages, the dynamic models of floating-capacitor voltages and neutral-point voltage are established. Moreover, the ACVB method based on the dynamic model of the neutral-point voltage is proposed by injecting the zero-sequence voltage. And the ACVB method based on the dynamic model of floating-capacitor voltages is proposed by introducing the adjustment variables. The proposed ACVB methods have the advantages of simple formula, definite physical meaning, and high accuracy. Furthermore, the output voltage quality and current quality are evaluated in term of total harmonic distortion and the effect of model parameter mismatch on the proposed ACVB methods is presented. Finally, the comparative simulation and experimental results verify the correctness of the proposed ACVB methods based on the dynamic model under different conditions. [ABSTRACT FROM AUTHOR]

Published

2018

62. A New H-Bridge Hybrid Modular Converter (HBHMC) for HVDC Application: Operating Modes, Control, and Voltage Balancing.

Author

Ghat, Mahendra B. and Shukla, Anshuman

Subjects

*CASCADE converters, *HIGH-voltage direct current transmission, *CAPACITORS, *VOLTAGE control, *ELECTRIC faults

Abstract

An H-bridge hybrid modular converter (HBHMC) is proposed for high-voltage direct current (HVDC) applications. It uses a wave-shaping circuit consisting of series-connected full-bridge submodules (FBSMs) at the output of the main H-bridge converter. For a three-phase system, three HBHMCs are connected either in series (series-HBHMC) or in parallel (parallel-HBHMC) across the dc-link. The operating modes of HBHMC, novel modulation strategies for voltage balancing of FBSMs, and control of HBHMC-based HVDC system are presented in this paper. A detailed comparison between HBHMC and other hybrid topologies is performed on the basis of required number of switches and capacitors. The HBHMC has the features of dc fault blocking capability, lower footprint structure, and extra degree of freedom for submodules capacitor voltage balancing. The efficacy of the HBHMC-based HVDC system for three-phase balanced and unbalanced grid conditions and its fault-tolerant capability are validated using PSCAD simulation studies. Furthermore, the feasibility of the proposed converter under normal and dc fault conditions and of the proposed capacitor voltage control scheme is validated experimentally by using a three-phase grid-connected HBHMC laboratory prototype. The results demonstrate the effectiveness of the proposed HBHMC topology, control techniques, and satisfactory responses of the HBHMC-based HVDC system. [ABSTRACT FROM AUTHOR]

Published

2018

63. A New Boost Switched-Capacitor Multilevel Converter With Reduced Circuit Devices.

Author

Barzegarkhoo, Reza, Moradzadeh, Majid, Zamiri, Elyas, Madadi Kojabadi, Hossein, and Blaabjerg, Frede

Subjects

*CASCADE converters, *CAPACITOR switching, *ELECTRIC potential, *POWER electronics, *SWITCHING circuits

Abstract

In this paper, a novel platform for the single phase switched-capacitor multilevel inverters (SCMLIs) is presented. It has several advantages over the classical topologies, such as an appropriate boosting property, higher efficiency, lower number of required dc voltage sources, and other accompanying components with less complexity and lower cost. The basic structure of the proposed converter is capable of making nine-level of the output voltage under different kinds of loading conditions. Hereby, by using the same two capacitors paralleled to a single dc source, a switched-capacitor (SC) cell is made that contributes to boosting the value of the input voltage. In this case, the balanced voltage of the capacitors can be precisely provided on the basis of the series–parallel technique and the redundant switching states. Afterward, to reach the higher number of output voltage levels, two suggested SC cells are connected to each other with a new extended configuration. Therefore, by the use of a reasonable number of required power electronic devices, and also by utilizing only two isolated dc voltage sources, which their magnitudes can be designed based on either symmetric or asymmetric types, a 17- and 49-level of the output voltage are obtained. Based on the proposed extended configuration, a new generalized version of SCMLIs is also derived. To confirm the precise performance of the proposed topologies, apart from the theoretical analysis and a complete comparison, several simulation and experimental results are also given. [ABSTRACT FROM AUTHOR]

Published

2018

64. A Novel High Step-Up Dual Switches Converter With Coupled Inductor and Voltage Multiplier Cell for a Renewable Energy System.

Author

Liu, Hongchen, Li, Fei, and Ai, Jian

Subjects

*CASCADE converters, *CAPACITORS, *ELECTRIC inductors, *VOLTAGE multipliers, *RENEWABLE energy sources

Abstract

A novel high step-up converter, which is suitable for a renewable energy system, is proposed in this paper. The proposed converter is composed of the dual switches structure, three-winding coupled inductor, and two voltage multiplier cells in order to achieve the high step-up voltage gain. The dual switches structure is beneficial to reduce the voltage stress and current stress of the switch. In addition, two multiplier capacitors are, respectively, charged during the switch-on period and switch-off period, which increases the voltage conversion gain. Meanwhile, the energy stored in the leakage inductor is recycled with the use of clamped capacitors. Thus, two main power switches with low on-resistance and low current stress are available. As the leakage inductor, diode reverse-recovery problem is also alleviated. Therefore, the efficiency is improved. This paper illustrates the operation principle of the proposed converter; discusses the effect of the leakage inductor; analyzes the influence of parasitic parameters on the voltage gain and efficiency, the voltage stresses and current stresses of power devices are shown; and a comparison between the performance of the proposed converter and the previous high step-up converters is performed. Finally, the prototype circuit with input voltage 20 V, output voltage 200 V, and rated power 200 W is operated to verify its performance. [ABSTRACT FROM AUTHOR]

Published

2016

65. Analysis and Design of a Single-Switch Forward-Flyback Two-Channel LED Driver With Resonant-Blocking Capacitor.

Author

Kim, Jong-Woo, Moon, Jung-Pil, and Moon, Gun-Woo

Subjects

*LIGHT emitting diodes, *ELECTRIC currents, *CAPACITORS, *CASCADE converters, *ELECTRIC inductors

Abstract

In order to balance the light-emitting-diode (LED) current in each channel, many active and passive methods have been investigated. Among the various methods, the passive method using the LLC converter with a blocking capacitor or flyback converter with a current-sharing transformer (CST) in the secondary side is one of the simplest methods because it does not use any active component. However, the LLC driver requires two main switches and external resonant inductor to obtain a wide output voltage range. Also, flyback with a CST requires an additional magnetic component for CST and high-voltage rated diodes, resulting in the limitation of the cost and system volume. In this paper, a single-switch forward-flyback driver for a two-channel LED is proposed. The most powerful advantage of the proposed driver is the cost effectiveness, since it eliminates additional magnetic component. Furthermore, due to the reduced-voltage stress on rectifier diodes compared to the flyback driver, the proposed driver achieves a higher efficiency. The prototype of the 150–100-V/0.3-A two-channel LED verifies the effectiveness of this paper. [ABSTRACT FROM PUBLISHER]

Published

2016

66. A Switched-Capacitor Submodule for Modular Multilevel HVDC Converters With DC-Fault Blocking Capability and a Reduced Number of Sensors.

Author

Elserougi, Ahmed A., Massoud, Ahmed M., and Ahmed, Shehab

Subjects

*CAPACITORS, *CASCADE converters, *HIGH-voltage direct current transmission, *DETECTORS, *DIELECTRIC devices

Abstract

Modular multilevel converters (MMCs) have become one of the most promising topologies for high-voltage dc–ac conversion. DC-side fault blocking capability of the MMC has prompted significant research in recent years. In this paper, a new switched capacitor submodule (SCSM) for MMCs is proposed which provides operation with DC fault blocking capability. In addition, successful voltage balancing is achieved with half the number of voltage sensors used with existing MMC cells. Generally, conventional sensor-based balancing techniques require a significant amount of measurements, 2m(N-1) voltage sensors, and 2m current sensors for an N-level m-phase MMC. The proposed cell will thus aid in reducing the complexity of the control system. A detailed illustration of the operational concept of the proposed architecture is presented in this paper. A comparison between the proposed SCSM and other existing MMC cells has been included to highlight the benefits of the proposed SCSM. A simulation model for an MMC-based HVDC system along with the proposed cell has been built to test its performance during normal as well as abnormal operating conditions. The simulation results show the effectiveness of the proposed architecture. [ABSTRACT FROM PUBLISHER]

Published

2016

67. A Novel Power Converter Topology for Electrostatic Precipitators.

Author

Vukosavic, Slobodan N., Peric, Ljiljana S., and Susic, Stanimir D.

Subjects

*CASCADE converters, *ELECTRIC network topology, *ELECTROSTATIC precipitation, *ELECTRIC potential, *INSULATED gate bipolar transistors

Abstract

In this paper, we introduced an improved transformer-based parallel-resonant converter, suitable for high voltage, high power dc loads. The resonant capacitors are connected in parallel with diodes of the high voltage rectifier, thus restraining dv/dt stress in high voltage circuits. The LC tank resonant frequency is well beyond the switching frequency, reducing in this way the VA rating of LC components. With rated load, the output current of the IGBT bridge is equal to zero at switching instants, and the switching losses are very low. Proposed subresonant circuit requires lower primary current for the given output power and it has reduced IGBT losses. Experimental setup delivers 79 kW with an efficiency of 96.78%. The paper explains the switching states of the devised topology, and provides the guidelines for designing the power transformer, the LC tank and controls. Analytical prediction of the performance curves is verified both in laboratory and by the field tests with an electrostatic precipitator plant. [ABSTRACT FROM AUTHOR]

Published

2016

68. Analysis and Design of Charge Pump-Assisted High Step-Up Tapped Inductor SEPIC Converter With an “Inductorless” Regenerative Snubber.

Author

Yao, Jia, Abramovitz, Alexander, and Smedley, Keyue Ma

Subjects

*ON-chip charge pumps, *CASCADE converters, *RENEWABLE energy sources, *ELECTRIC inductors, *COMPUTER simulation, *SOLAR cells

Abstract

This paper introduces a SEPIC-derived converter suited for alternative energy generation applications. The proposed converter utilizes tapped inductor and charge pump techniques to achieve high step-up gain and a passive regenerative snubber to attain high efficiency. Compared with earlier counterparts, the proposed converter has the advantage of continuous input current, which can be helpful in attaining accurate tracking of maximum power point of solar panels. The paper presents principle of operation, theoretical analysis, and design guidelines. Theoretical expectations were confirmed by simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2015

69. Interleaved Buck Converter With Continuous Input Current, Extremely Low Output Current Ripple, Low Switching Losses, and Improved Step-Down Conversion Ratio.

Author

Esteki, Morteza, Poorali, Behzad, Adib, Ehsan, and Farzanehfard, Hosein

Subjects

*ELECTRIC current converters, *ELECTRIC currents, *CASCADE converters, *ELECTRIC power distribution, *ELECTRIC power conversion

Abstract

This paper proposes an interleaved buck converter (IBC) with continuous input current, extremely low output current ripple, low switching losses, and improved step-down conversion ratio. Unlike the conventional IBC, the proposed converter has a continuous input current, and its output current ripple is extremely low. The proposed converter has a lower voltage stress in comparison to the conventional IBC and can also provide a high step-down ratio, which makes it a proper choice for high-power applications where a nonisolated step-down converter with low output current ripple and continuous input current is required. Also, the proposed converter can provide current sharing between two interleaved modules without using additional current-sharing control method. All of these benefits are obtained without any additional stress on the circuit components. A prototype converter with 200-V input and 24-V–10-A output is implemented to verify the theoretical analysis. Operational principles and experimental results are presented in this paper. [ABSTRACT FROM PUBLISHER]

Published

2015

70. Implementation of Bridgeless Cuk Power Factor Corrector With Positive Output Voltage.

Author

Yang, Hong-Tzer, Chiang, Hsin-Wei, and Chen, Chung-Yu

Subjects

*ELECTRIC power factor, *ELECTRIC circuit design & construction, *CASCADE converters, *VOLTAGE control, *ZERO current switching

Abstract

A single-phase bridgeless Cuk ac/dc power factor correction (PFC) rectifier with positive output voltage is proposed in this paper. For low output voltage product applications, the rectifier is designed to convert high input voltage to low output voltage. Due to no bridge diodes required and thus decreased input conduction losses, the proposed rectifier efficiency can be improved. The proposed rectifier operates in discontinuous conduction mode, and the current-loop circuit is hence not needed. In addition, only a single switch is used in the rectifier to simplify the control circuit design. A simple translation method to have the positive output voltage in the Cuk converter is presented in the rectifier to reduce the component counts and the cost. The operational principles, steady-state analysis, and design procedure of the proposed rectifier are addressed in detail in this paper. Simulation and experimental results obtained from a 150-W rated prototype circuit with input of 90–130 Vrms, 60 Hz, and output of 48 Vdc have verified the validity of the proposed rectifier. [ABSTRACT FROM PUBLISHER]

Published

2015

71. The Use of Averaged-Value Model of Modular Multilevel Converter in DC Grid.

Author

Xu, Jianzhong, Gole, Aniruddha M., and Zhao, Chengyong

Subjects

*CASCADE converters, *HIGH-voltage direct current transmission, *SMART power grids, *IDEAL sources (Electric circuits), *ELECTRICAL engineering

Abstract

This paper investigates the applicability of averaged-value models (AVMs) for modular multilevel converters (MMCs) operating in a voltage-sourced converter-based-high-voltage dc (VSC-HVDC) grid. The AVM models are benchmarked by comparison with a detailed electromagnetic transient model of the grid, including a fully detailed MMC model. Analysis results show that the AVM is only effective as long as the capacitors are large enough to maintain nearly constant voltage across each MMC submodule. This paper also shows that previously developed MMC averaged models are not able to accurately simulate the transients under dc fault conditions. This paper introduces topology changes to a previously proposed averaged model that results in much improved simulation for such conditions. This paper also shows that the model can be used effectively to study HVDC grids with significant time savings. [ABSTRACT FROM AUTHOR]

Published

2015

72. Model Predictive Control With a Reduced Number of Considered States in a Modular Multilevel Converter for HVDC System.

Author

Moon, Ji-Woo, Gwon, Jin-Su, Park, Jung-Woo, Kang, Dae-Wook, and Kim, Jang-Mok

Subjects

*PREDICTIVE control systems, *CASCADE converters, *HIGH-voltage direct current transmission, *CAPACITORS, *ELECTRICAL engineering

Abstract

This paper proposes a model predictive control (MPC) method for modular-multilevel-converter (MMC) high-voltage direct current (HVDC). To control the MMC-HVDC system properly, the ac current, circulating current, and submodule (SM) capacitor voltage are taken into consideration. The existing MPC methods for the MMC-HVDC system utilize weighting factors to configure the cost function in combinations of the SM capacitor voltage balancing algorithm, ac current control, and circulating current control. Because all combinations of the switch states are considered in order to minimize the cost function, their possible combinations increase geometrically according to the increase of the level of the MMC, which is a significant disadvantage. This paper proposes a new MPC method with a reduced number of states for ac current control, circulating current control, and the SM capacitor voltage-balancing algorithm. The proposed cost functions are divided into three types according to their control purposes. Each cost function determines the minimum number of states for controlling the ac current, circulating current, and SM capacitor voltage. The efficacy of the proposed controlling method is verified through simulation results using PSCAD/EMTDC. [ABSTRACT FROM AUTHOR]

Published

2015

73. Modular Multilevel Converters for HVDC Applications: Review on Converter Cells and Functionalities.

Author

Nami, Alireza, Jiaqi Liang, Dijkhuizen, Frans, and Demetriades, Georgios D.

Subjects

*CASCADE converters, *HIGH-voltage direct current transmission, *MODULAR design, *DIRECT currents, *VOLTAGE-frequency converters

Abstract

In this paper, the principle of modularity is used to derive the different multilevel voltage and current source converter topologies. The paper is primarily focused on high-power applications and specifically on high-voltage dc systems. The derived converter cells are treated as building blocks and are contributing to the modularity of the system. By combining the different building blocks, i.e., the converter cells, a variety of voltage and current source modular multilevel converter topologies are derived and thoroughly discussed. Furthermore, by applying the modularity principle at the system level, various types of high-power converters are introduced. The modularity of the multilevel converters is studied in depth, and the challenges as well as the opportunities for high-power applications are illustrated. [ABSTRACT FROM AUTHOR]

Published

2015

74. Analysis and Operation of Modular Multilevel Converters With Phase-Shifted Carrier PWM.

Author

Ilves, Kalle, Harnefors, Lennart, Norrga, Staffan, and Nee, Hans-Peter

Subjects

*CASCADE converters, *PHASE shifters, *PULSE width modulation, *SWITCHING theory, *CAPACITORS, *ELECTRIC potential

Abstract

Many publications have been presented on the modulation and control of the modular multilevel converter, some of which are based on phase-shifted carrier modulation. This paper presents an analysis of how the switching frequency affects the capacitor voltages, circulating currents, and alternating voltages using phase-shifted carrier modulation. It is found that switching frequencies that are integer multiples of the fundamental frequency should be avoided as they can cause the capacitor voltages to diverge. Suitable switching frequencies are derived for which the arm and line quantities will be periodic with symmetric operating conditions in the upper and lower arms. Thus, the practical outcome of this paper is a detailed description of how the switching frequency should be chosen in order to achieve advantageous operating conditions. The theoretical results from the analysis are validated by both simulations and experimental results. [ABSTRACT FROM AUTHOR]

Published

2015

75. Optimized Control Strategy Based on Dynamic Redundancy for the Modular Multilevel Converter.

Author

Gaoren Liu, Zheng Xu, Yinglin Xue, and Geng Tang

Subjects

*DYNAMICAL systems, *CASCADE converters, *ELECTRONIC modulation, *TECHNOLOGICAL innovations, *CAPACITORS

Abstract

Considering the synthetical effects of the ac system and the dc system, this paper proposes two novel indexes, the dynamic redundancy and the utilization ratio of the submodules. On this basis, the nearest level control is applied as the modulation method and an optimized control strategy based on the dynamic redundancy for the modular multilevel converter (MMC) is proposed. One of the main innovations is that the reference value of the capacitor voltage is derived according to the maximum output voltage of each converter arm and the safety margin which can be adjusted artificially. Unlike previous strategies, the redundancy can be adjusted dynamically, and the utilization ratio of the submodules can be effectively improved. In addition, the capacitor voltage and the inner stress are reduced, and the fault ride-through capability of the system can be enhanced. In particular, the strategy under abnormal operating conditions is also detailed in this paper. A model of two-terminal MMC-high-voltage direct current system is built in PSCAD/EMTDC, and the simulation result proves the validity and the feasibility of the proposed strategy. [ABSTRACT FROM AUTHOR]

Published

2015

76. 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

77. Power Router for Meshed Systems Based on a Fractionally Rated Back-to-Back Converter.

Author

Kandula, Rajendra Prasad, Iyer, Amrit, Moghe, Rohit, Hernandez, Jorge E., and Divan, Deepak

Subjects

*CASCADE converters, *ENERGY consumption, *WIND power, *ELECTRIC power distribution grids, *ELECTRIC transformers, *ELECTRIC power transmission

Abstract

Increasing energy demand and growth of wind generation have significantly increased the stress on the electric grid. The low investment in transmission infrastructure necessitates adoption of methods for efficient use of existing resources. Power converter-based FACTS devices, capable of dynamic power-flow control, have been the preferred solution to maximize utilization of existing infrastructure, but implementation of traditional FACTS solutions at transmission level voltages is complex and cost prohibitive. This paper proposes a power router (PR) for dynamic power-flow control in a meshed network. The proposed PR is realized by augmenting a transformer with a fractionally rated back-to-back converter. The main advantages of the proposed converter are the fractional converter rating and reduced low-frequency transformer requirement compared to the traditional FACTS solutions. This paper outlines the proposed PR topology, control range, controller design and demonstrates the functionality through simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2014

78. Inductor Current Zero-Crossing Detector and CCM/DCM Boundary Detector for Integrated High-Current Switched-Mode DC–DC Converters.

Author

Michal, Vratislav

Subjects

*CASCADE converters, *ELECTRIC inductors, *COMPARATOR circuits, *CURRENT mirrors, *POWER transistors, *CAPACITORS

Abstract

This paper presents two circuits that allow us to accurately detect either the inductor current zero crossing, or the continuous/discontinous conduction modes boundary in the switched-mode dc-dc converters. Achieved detection accuracy allows us to improve the control and efficiency of the integrated high-output current converters, i.e., converters with low-resistance power switches. Detection is based on the voltage zero-cross detector, which provides ideally zero input-referred offset and very fast results. The concept of voltage polarity detector is based on the association of a dynamic current mirror and a simple autozero comparator. This paper describes the main concept of both circuits, aspects of the design allowing us to achieve high accuracy, and presents obtained results. Circuits' performances are demonstrated on the integrated step-down dc-dc converter with IOUT = 2.5 A 30-mΩ NMOS power stage. Measured accuracy of the detection is in order of <;15 mA. [ABSTRACT FROM AUTHOR]

Published

2014

79. Center-Cell Concentration Structure of a Cell-to-Cell Balancing Circuit With a Reduced Number of Switches.

Author

Moon-Young Kim, Jun-Ho Kim, and Gun-Woo Moon

Subjects

*ELECTRIC switchgear, *ELECTRIC circuits, *CASCADE converters, *CHARGE transfer, *LITHIUM-ion batteries

Abstract

Among the various cell balancing circuits for series-connected batteries, the bidirectional cell-to-cell balancing structure using two switches per cell shows good balancing ability. However, an increase in the number of switches leads to an increase in both cost and size. To reduce the number of switches, this paper proposes a new cell-to-cell balancing circuit with a center-cell concentration structure. The proposed circuit collects the charges of an overcharged cell into the center cell, and then the collected charges are redistributed to the other cells. The proposed circuit has a unidirectional balancing structure with single switch per cell. However, it can achieve competitive balancing ability when compared with the bidirectional structure. In this paper, the operational principles of the proposed circuit are analyzed, and a comparison between the conventional and proposed circuits is shown. To verify the validity of the proposed circuit, experiments with 15.5-Ah batteries are carried out, and the experimental results demonstrate the improved cell balancing ability although a single switch is used per cell. [ABSTRACT FROM AUTHOR]

Published

2014

80. Single Power-Conversion AC--DC Converter With High Power Factor and High Efficiency.

Author

Yong-Won Cho, Jung-Min Kwon, and Bong-Hwan Kwon

Subjects

*ELECTRIC power, *ALTERNATING currents, *CASCADE converters, *ALGORITHMS, *ELECTRIC switchgear

Abstract

This paper proposes a single power-conversion ac-dc converter with high power factor and high efficiency. The proposed converter is derived by integrating a full-bridge diode rectifier and a series-resonant active-clamp dc-dc converter. To obtain a high power factor without a power factor correction circuit, this paper proposes a novel control algorithm. The proposed converter provides single power-conversion by using the novel control algorithm for both power factor correction and output control. Also, the active-clamp circuit clamps the surge voltage of switches and recycles the energy stored in the leakage inductance of the transformer. Moreover, it provides zero-voltage turn-on switching of the switches. Also, a series-resonant circuit of the output-voltage doubler removes the reverse-recovery problem of the output diodes. The proposed converter provides maximum power factor 0.995 and maximum efficiency of 95.1% at the full load. The operation principle of the converter is analyzed and verified. Experimental results for a 400 W ac-dc converter at a constant switching frequency of 50 kHz are obtained to show the performance of the proposed converter. [ABSTRACT FROM AUTHOR]

Published

2014

81. 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

82. Dynamic Electro-Magnetic-Thermal Modeling of MMC-Based DC?DC Converter for Real-Time Simulation of MTDC Grid.

Author

Lin, Ning and Dinavahi, Venkata

Subjects

*CASCADE converters, *ELECTRIC power distribution grids, *ELECTRIC power distribution equipment, *ELECTRIC power systems, *ELECTRIC potential

Abstract

The model of a modular multilevel converter (MMC) determines the extent of critical circuit information that electromagnetic transient simulations can reveal. In this paper, two MMC models are proposed for efficient real-time hardware-in-the-loop (HIL) emulation on the field-programmable-gate-arrays (FPGA). The nonlinear switch-based model employing the insulated-gate bipolar transistor (IGBT) dynamic curve-fitting model considers factors affecting its transient performance so that device-level behavior such as power loss and junction temperature can be reproduced accurately in the electro-magnetic-thermal simulation of a power converter for its design evaluation. Meanwhile, regarding the MMC submodule as a transmission line stub achieves faster computation speed and enables the formation of a hybrid arm to save FPGA hardware resources. As the large network that the MMC presents is burdensome for real-time execution with a small time-step, circuit simplification based on partitioning and merging is conducted. Hardware implementation of a three-terminal high-voltage direct-current system containing an MMC-based dc–dc converter is carried out and the efficacy of proposed models is validated by comparing HIL emulation results with the offline simulation tool PSCAD/EMTDC. [ABSTRACT FROM AUTHOR]

Published

2018

83. An Isolated Bidirectional Interleaved Converter With Minimum Active Switches and High Conversion Ratio.

Author

Shen, Chih-Lung, Liou, Heng, Liang, Tsair-Chun, and Gong, Hong-Ze

Subjects

*CASCADE converters, *ELECTRIC switchgear, *DC-to-DC converters, *DIODES, *ELECTRIC inductors, *SNUBBERS (Electrical engineering), *RENEWABLE energy sources

Abstract

This paper presents an isolated bidirectional interleaved converter with minimum active switches to achieve high conversion ratio. The proposed converter has symmetric structure for easy control, and incorporates two coupled inductors for galvanic isolation and high voltage ratio achievement. A dual-inductor-capacitor-diode (LCD) snubber with common resonant inductor at low-voltage side is in charge of leakage energy recycling for efficiency improvement. In addition, the converter can obtain interleaved terminal current at low-voltage side for lowering current ripples, no matter in boost mode or buck mode. Finally, a 400-W prototype is built for validation, where the experimental results indicate that the highest efficiencies in boost and buck modes are 95.5% and 95.4%, respectively. [ABSTRACT FROM PUBLISHER]

Published

2018

84. DC-Link Capacitor-Current Ripple Reduction in DPWM-Based Back-to-Back Converters.

Author

Tcai, Anatolii, Lee, Kyo-Beum, and Shin, Hye-Ung

Subjects

*DIRECT currents, *CASCADE converters, *ELECTRIC inverters, *POWER transistors, *EXPERIMENTS

Abstract

This paper proposes an improved offset selection method for discontinuous-pulse-width-modulation (DPWM)-based back-to-back converters to reduce dc-link current ripple. DPWM is introduced to power converters to diminish the stress on power transistors and prolong their lifespan. However, when using the DPWM method, the dc-link current ripple is increased in nonswitching regions of the power transistors. Moreover, in DPWM-based back-to-back converters, the dc-link current ripple reaches its maximum when the two transistors of both inverters are clamped in opposite directions. Therefore, the dc-link capacitors endure more stress, resulting in decreased life duration. To overcome this issue, the switching method should consider the clamping periods, when the current ripple increases. This can be achieved by modifying the DPWM offset, so that the clamping states of both converters are matched. The effectiveness of the proposed method is confirmed by both simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

85. A New Negative Output Buck–Boost Converter with Wide Conversion Ratio.

Author

Ding, Shumin and Wang, Faqiang

Subjects

*CASCADE converters, *ENERGY conversion, *STEADY state conduction, *CAPACITORS, *WAVE analysis

Abstract

In this paper, a new negative output (N/O) buck–boost converter, which can be applied for applications that need wide range of inverse voltage, is proposed. The steady-state, small-signal model and power losses of the proposed converter operating in a continuous conduction mode are analyzed. Comparisons among the traditional buck–boost converter, N/O hybrid buck–boost converter and N/O self-lift Luo converter are presented, and it is found that the proposed converter possesses a widest voltage conversion ratio in these four converters. Finally, a prototype is built, and the simulated waveforms from the PSIM software and the experimental results are presented for validation. [ABSTRACT FROM AUTHOR]

Published

2017

86. Topology and Capacitor Voltage Balancing Control of a Symmetrical Hybrid Nine-Level Inverter for High-Speed Motor Drives.

Author

Wang, Kui, Zheng, Zedong, Wei, Dabo, Fan, Boran, and Li, Yongdong

Subjects

*ELECTRIC inverters, *MOTOR drives (Electric motors), *PULSE width modulation, *CASCADE converters, *ELECTRICAL engineering

Abstract

In order to increase the output voltage levels and reduce the isolated dc sources, a symmetrical hybrid nine-level inverter for high-speed motor drive applications is presented in this paper. Each phase of this inverter is composed of a five-level dc/dc converter cell and an H-bridge cell. The dc/dc converter is operated at high frequency with low-voltage devices and the H-bridge is operated at fundamental frequency with high-voltage devices. The three phases are connected to a common dc-link and each drives an isolated winding of an open-winding motor. The operating principles and modulation method are introduced. A detailed analysis of the average currents through the flying capacitor and neutral point of the dc-link is presented and a capacitor voltage balancing method based on phase-shifted pulse-width modulation is proposed. Simulation and experimental results are presented to demonstrate the feasibility of this topology and control method. [ABSTRACT FROM PUBLISHER]

Published

2017

87. Modified Boost Derived Hybrid Converter: Redemption Using FCM.

Author

Chauhan, Avneet K., Vakacharla, Venkata R., Reza, M. M., Raghuram, M., and Singh, Santosh Kumar

Subjects

*CASCADE converters, *HYBRID electric vehicles, *ELECTROMAGNETIC interference, *HARMONIC distortion (Physics), *ELECTRICAL engineering

Abstract

Boost-derived hybrid converter (BDHC) is a single-stage converter that produces both dc and ac output voltages. The operation of BDHC under continuous conduction mode is satisfactory. However, the nonzero discontinuous conduction mode (NZ-DCM) and standalone ac operation restrict the stable operation of the converter. To mitigate these limitations, modified BDHC (MBDHC) is proposed in this paper. The main idea behind these changes is to redeem NZ-DCM by forced continuous conduction mode (FCM). The adverse effect of NZ-DCM in a BDHC is analyzed in terms of ac output voltage total harmonic distortion, and dc output voltage ripple. This analysis is further extended for MBDHC to highlight the benefits of FCM. Moreover, for hybrid loads, the efficiency of MBDHC is compared with its counterpart BDHC and cascaded boost inverter. [ABSTRACT FROM PUBLISHER]

Published

2017

88. PWM Converter Integrating Switched Capacitor Converter and Series-Resonant Voltage Multiplier as Equalizers for Photovoltaic Modules and Series-Connected Energy Storage Cells for Exploration Rovers.

Author

Uno, Masatoshi and Kukita, Akio

Subjects

*PULSE width modulation transformers, *CASCADE converters, *SWITCHED capacitor circuits, *ELECTRIC potential, *PHOTOVOLTAIC power generation

Abstract

Power systems for exploration rovers tend to be complex as three separate converters are necessary; in addition to a main dc–dc converter and cell equalizer for rechargeable energy storage cells, an equalizer for photovoltaic (PV) modules is desirably equipped in order to preclude negative impacts of partial shading. This paper proposes the pulse width modulation (PWM) converter integrating voltage equalizers for PV modules and energy storage cells. The proposed integrated converter comprises a switched capacitor converter, PWM buck converter, and series-resonant voltage multiplier that perform PV equalization, power conversion from the PV modules to the load, and cell equalization, respectively. Three converters can be integrated into a single unit with reducing the total switch counts, achieving not only system-level but also circuit-level simplifications. The derivation procedure of the integrated converter is explained, followed by the operation analysis. Experimental tests were performed using series-connected supercapacitor (SC) modules and solar array simulators to emulate a partial shading condition. With the integrated converter, the extractable maximum power from the PV modules significantly increased while voltage imbalance of SC modules was adequately eliminated, demonstrating the integrated performance of the proposed converter. [ABSTRACT FROM AUTHOR]

Published

2017

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

Author

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

Subjects

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

Abstract

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

Published

2017

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

Author

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

Subjects

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

Abstract

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

Published

2017

91. SiC-Based Z-Source Resonant Converter With Constant Frequency and Load Regulation for EV Wireless Charger.

Author

Zeng, Hulong and Peng, Fang Z.

Subjects

*ELECTRIC properties, *SILICON carbide, *CIRCUIT resonance, *CASCADE converters, *ELECTRICAL load, *ELECTRIC potential

Abstract

Traditional load regulation methods for a resonant converter mainly rely on frequency modulation. It is always a tradeoff between the design of the resonant network and the range of load. Especially for wireless power transfer (WPT) systems, the resonant network usually has a high quality factor. Small variation on frequency leads to huge drop in gain and efficiency. Due to this problem, many WPT systems are unregulated and they need one or two more front-end stages to regulate the dc bus voltage and perform power factor correction (PFC). In order to lower the cost and complexity of two- or three-stages structure, a single-stage solution with a silicon carbide (SiC) based Z-source resonant converter (ZSRC) was recently proposed. The Z-source network provides high reliability as being immune to shoot-through problems. Additionally, a ZSRC can boost the dc bus voltage while the traditional voltage-source inverter can only produce a lower voltage. However, the load regulation of this new topology has not been addressed. Two effective load regulation methods with constant frequency are presented for this SiC-based ZSRC specifically. Operation principle of the two load regulation methods are described in this paper. Experimental results based on a 200-W scale-down prototype with a full-bridge series resonant dc–dc converter are presented to illustrate the mechanism of these two methods. [ABSTRACT FROM AUTHOR]

Published

2017

92. Bilinear Discrete-Time Modeling and Stability Analysis of the Digitally Controlled Dual Active Bridge Converter.

Author

Shi, Ling, Lei, Wanjun, Li, Zhuoqiang, Huang, Jun, Cui, Yao, and Wang, Yue

Subjects

*DISCRETE-time systems, *STABILITY theory, *CASCADE converters, *ELECTRIC resistance, *CAPACITORS

Abstract

Dual active bridge (DAB) converters have been widely used in distributed power systems and energy storage equipment. However, the inherent nonlinearity of the DAB converters can cause stability problem, such as output voltage oscillation. In this paper, the dynamic behavior and stability of a digitally controlled DAB converter with a closed-loop controller are studied. First, to accurately study the nonlinear dynamics and stability in a DAB converter, a bilinear discrete-time model considering the output capacitor equivalent series resistance (ESR) and the digital control delay in circuit is established. Based on the model, the nonlinear dynamic characteristic and stability of the DAB converter versus the control parameter are studied. Furthermore, extensive analyses are performed to study the effect of the transformer leakage inductance and the output capacitor ESR on the stability boundaries of the control parameter. The accuracy of the model and the theoretical analyses are validated by simulation and experimental results. The proposed model of the digitally controlled DAB converter can accurately predict the stability boundaries, which can be effectively applied to the design of the system parameters and guarantee stable operation of the converter. [ABSTRACT FROM AUTHOR]

Published

2017

93. A Simplified Space-Vector Modulation Algorithm for Four-Leg NPC Converters.

Author

Rojas, Felix, Cardenas, Roberto, Kennel, Ralph, Clare, Jon C., and Diaz, Matias

Subjects

*CASCADE converters, *ELECTRONIC modulation, *VECTOR analysis, *ELECTRIC switchgear, *ELECTRIC network topology

Abstract

To interface generation sources and loads to four-wire distribution networks it is important to use power converters and modulation methods, which provide high performance, flexibility, and reliability. To achieve these goals, this paper proposes a simple and efficient space vector modulation (SVM) algorithm in $\alpha \beta \gamma$ coordinates for neutral point clamped (NPC) converters. The proposed SVM method reduces a 3-D ($\alpha \beta \gamma$) search amongst modulating vectors into a simple 2-D ( $\alpha \beta$) problem. Moreover, the algorithm provides full utilization of the dc-link voltage and full utilization of the redundant vectors, and it can be applied to any other four-leg converter topology. The proposed SVM has been successfully validated using a 6-kW three-level four-leg NPC converter, achieving control over the voltages of the dc-link capacitors and a simple definition of the switching patterns for shaping the frequency spectrum. [ABSTRACT FROM AUTHOR]

Published

2017

94. Novel Hybrid LLC Resonant and DAB Linear DC?DC Converter: Average Model and Experimental Verification.

Author

Liu, Chuang, Liu, Haiyang, Cai, Guowei, Cui, Shumei, Liu, Haijun, and Yao, Hang

Subjects

*CASCADE converters, *ELECTRIC current converters, *ROTARY converters, *CAPACITORS, *CIRCUIT elements

Abstract

A novel hybrid LLC resonant and dual active bridge (DAB) linear dc–dc converter is proposed as bus converter, which can achieve soft switching and constant output voltage gain at both the open-loop light load and closed-loop heavy load conditions. This paper focuses on its continuous-time average modeling in detail based on the dc output voltage, the first order terms of two transformer currents and the resonant capacitor voltage, which results in a seven-order model. Additionally, the total control-to-output transfer function is derived for the proposed hybrid converter dynamic analysis. The experimental results have verified that the proposed model can correctly match the small-signal frequency response, and compare with DAB, the related analysis based on the proposed model shows the novel hybrid converter can have a better output voltage response. [ABSTRACT FROM PUBLISHER]

Published

2017

95. A ZVS-PWM Full-Bridge Converter With Reduced Conduction Losses.

Author

Wijeratne, Dunisha S. and Moschopoulos, Gerry

Subjects

*PULSE width modulation, *CASCADE converters, *ELECTRIC conductivity, *ZERO voltage switching, *CAPACITORS, *ELECTRIC discharges

Abstract

A new soft-switching pulse-width-modulated (PWM) full-bridge converter is proposed in this paper. The proposed converter has zero voltage switching (ZVS) in all its switches with fewer conduction losses than other ZVS-PWM full-bridge converters, due to a novel auxiliary circuit scheme. In this paper, the operation of the new converter is explained and analyzed, a design procedure is presented and demonstrated with an example, and experimental results that confirm the feasibility of the converter are also presented. [ABSTRACT FROM AUTHOR]

Published

2014

96. A Novel Single-Phase Buck PFC AC–DC Converter With Power Decoupling Capability Using an Active Buffer.

Author

Ohnuma, Yoshiya and Itoh, Jun-Ichi

Subjects

*ELECTRIC power factor, *AC DC transformers, *PULSATION (Electronics), *HARMONIC distortion (Physics), *CAPACITORS, *CASCADE converters

Abstract

This paper discusses a new circuit configuration and a new control method for a single-phase ac–dc converter with power factor (P.F.) correction and a power pulsation decoupling function. The proposed converter can achieve low total harmonic distortion (THD) on the input current and the power pulsation decoupling function between the input and output sides, which allows low output voltage ripple even on a small output energy buffer at the same time using an active buffer. Therefore, the proposed converter does not require large smoothing capacitors or large smoothing inductors. The buffering energy is stored by a small capacitor, which controls the variation of the capacitor voltage through the active buffer. In this paper, the fundamental operations of the proposed converter are investigated experimentally. The experimental results reveal that the input current THD is 1.44%, the rate of the output voltage ripple is 6.33%, and the input P.F. is over 99%. In addition, a maximum efficiency of over 96% is obtained for a 750-W prototype converter. [ABSTRACT FROM PUBLISHER]

Published

2014

97. An Optimized SVPWM Strategy for Five-Level Active NPC (5L-ANPC) Converter.

Author

Guojun Tan, Qingwei Deng, and Zhan Liu

Subjects

*CASCADE converters, *PULSE width modulation, *ELECTRIC potential, *SWITCHING circuits, *CAPACITORS

Abstract

The five-level active neutral-point-clamped (5L-ANPC) converter has been widely studied for its excellent performance in high-power medium-voltage applications. This paper analyzes the space vector pulse width modulation (SVPWM) strategy of the 5L-ANPC converter in the virtual coordinate, and presents an optimized control strategy which can balance the neutral point (NP) voltage and avoid the dead-time effects for the first time. In this strategy, on one hand, the 125 space vectors are combined by 96 triangles in the seven-segment vector synthesis method, then the triangles are divided into seven categories which have different characteristics of balancing the NP voltage, and every category has its own principles to choose the vector sequence and compute the vector durations. On the other hand, the dead-time effects of the 5L-ANPC converter are studied in detail and the transitions between different switching states are constrained in the optimized control strategy to avoid the dead-time effects that cannot be compensated by traditional pulse-based dead-time compensation methods. Finally, the optimized SVPWM strategy is experimentally verified in this paper. [ABSTRACT FROM AUTHOR]

Published

2014

98. Reduced-Order Model and Control Approach for the Boost Converter With a Voltage Multiplier Cell.

Author

Dupont, Fabrício Hoff, Rech, Cassiano, Gules, Roger, and Pinheiro, José Renes

Subjects

*REDUCED-order models, *REDUCED-order controllers, *CASCADE converters, *ANALOG multipliers, *ELECTRIC inductors, *ELECTRIC switchgear, *INTEGRATED circuits, *VOLTAGE-controlled oscillators, *CAPACITORS

Abstract

The boost converter with a voltage multiplier cell allows the static gain extension by means of the switching capacitor technique, reducing the duty cycle needed to achieve the same voltage gain when compared to the conventional boost converter. However, the modeling of this converter is complex and requires the use of advanced techniques due to the resonant inductor. Thus, this paper aims to present a reduced-order model of this converter without the resonant energy exchange between the capacitors, so that the state-space averaging technique can be applied assuming small ripple in the state variables. In addition, this paper presents the design of a control system for the boost converter with a voltage multiplier cell. The adopted strategy employs an inner loop to control the input current and an outer loop for the output voltage regulation. Extensive analysis based on simulations and an experimental prototype demonstrate that the proposed modeling, although simplified, is sufficient for an adequate control system design, ensuring good voltage regulation, and fast transient responses. [ABSTRACT FROM PUBLISHER]

Published

2013

99. Phase-Disposition PWM Implementation for a Hybrid Multicell Converter.

Author

Lezana, Pablo, Aceiton, Roberto, and Silva, César

Subjects

*CASCADE converters, *CATHODE ray oscillographs, *ELECTRONIC modulation, *CAPACITORS, *ELECTRIC potential

Abstract

Many different topologies based on the multilevel converter approach have been presented in the last decades. In order to obtain improved output waveforms, several modulation techniques have been developed for such converters. Some of those modulation schemes can be directly applied to almost any multilevel converter, while others require significant adaptation in order to be implemented in certain specific converters. This paper presents the implementation of a phase-disposition level-shifted pulsewidth modulation to the recently introduced hybrid multicell converter (HMC). The HMC uses a flying capacitor module on each cell to generate a positive variable dc-link voltage. The variable dc link is inverted at fundamental switching frequency by an H-bridge to generate the cell output voltage. It is desirable to use PD-PWM for its well-known high-performance waveforms. In this paper, a state-machine decoder is developed to balance the floating capacitor voltages and to equalize the supplied power for the series-connected cells of the HMC when using a PD-PWM pattern. Experimental results obtained from a 10-kW prototype are presented, confirming the good-quality waveforms of the HMC modulated with PD-PWM and the adequate balance of all floating capacitors. [ABSTRACT FROM PUBLISHER]

Published

2013

100. Voltage Balancing and Fluctuation-Suppression Methods of Floating Capacitors in a New Modular Multilevel Converter.

Author

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

Subjects

*CASCADE converters, *ELECTRIC potential, *DIODES, *FLUCTUATIONS (Physics), *ELECTRIC capacity

Abstract

Modular multilevel converter (MMC) is a newly emerging multilevel topology for high-voltage applications during recent years. In this paper, a new MMC is proposed, and the structure and operating principle are analyzed. Owing to the cascaded basic cells without multiwinding transformer, the voltage balancing of floating capacitors must be considered. However, the voltage fluctuation also exists, and theoretical analysis indicates that the amplitude is inversely proportional to the fundamental frequency. This paper has proposed a voltage-fluctuation-suppression method which can reduce the amplitude of the voltage fluctuation in low-frequency region. It can also be used in motor driving with pump/blowerlike load at low frequency and improve the start-up performance significantly. A low-power three-phase five-level prototype is designed and built up to demonstrate the validity of this method. [ABSTRACT FROM PUBLISHER]

Published

2013