Showing total 219 results

51. Integrated DC–DC Converter Based Grid-Connected Transformerless Photovoltaic Inverter With Extended Input Voltage Range.

Author

Anurag, Anup, Deshmukh, Nachiketa, Maguluri, Avinash, and Anand, Sandeep

Subjects

*CONVERTERS (Electronics), *ELECTRIC potential, *DIRECT currents, *ELECTRIC inverters, *PHOTOVOLTAIC power systems

Abstract

Owing to low cost, small size, and low weight, transformerless inverters became prominent in single-phase grid connected photovoltaic (PV) systems. Key issues pertaining to these inverters include suppression of common mode (CM) leakage current and improvement of conversion efficiency. Achieving higher efficiency in single-phase grid-connected photovoltaic systems depends on the number of stages involved in feeding power to the grid, predominantly, if the PV array voltage is less than the peak value of the grid voltage. In this paper, an integrated dc–dc converter based grid-connected transformerless PV inverter is proposed which is aimed at maintaining high efficiency, even if the PV array voltage falls below the peak value of grid voltage (efficient operation at an extended input voltage range). A modulation strategy is discussed in order to minimize the flow of CM leakage current. Further, the efficiencies of certain transformerless inverter topologies are analyzed and compared with that of the proposed topology. Detailed simulation studies are carried out in MATLAB/Simulink environment to verify the analysis. Experimental results for a scaled down laboratory prototype are included as a proof-of-concept to validate the claims. [ABSTRACT FROM AUTHOR]

Published

2018

52. Investigation of a Single-Phase Multilevel Inverter Based on Series/Parallel-Connected H-Bridges.

Author

de Paula Dias Queiroz, Antonio, Jacobina, Cursino Brandao, Maia, Ayslan Caisson Noroes, Melo, Victor Felipe Moura Bezerra, and da Silva, Ivan

Subjects

*ELECTRIC inverters, *ELECTRIC potential, *SIMULATION methods & models, *ELECTRIC current converters, *POTENTIAL energy

Abstract

This paper investigates a multilevel inverter composed of series/parallel-connected H-bridges. The presented structure can be used for applications in which the use of semiconductor switches with low-voltage and low-current ratings is intended. A comprehensive system model, an overall control strategy to adjust the output voltage with constant magnitude and frequency, and a level-shifted PWM (LS-PWM) strategy based on a voltage vectors unidimensional analysis and a plane analysis are presented. The LS-PWM is capable of mitigating the low-frequency circulating current, thus generating multilevel voltage signals with low harmonic distortion, maximum number of levels, and low dv/dt. In addition, considering a wide range of values of voltages and currents and various power levels, the total converter losses are reduced compared with the conventional multilevel converters. Two multilevel conventional inverters with the same number of semiconductor switches are used for comparison. Simulation and experimental results demonstrate the feasibility of the studied converter. [ABSTRACT FROM AUTHOR]

Published

2018

53. Design and Implementation of Transformer-Based Multilevel Inverter Topology With Reduced Components.

Author

Behara, Siva, Sandeep, N., and Yaragatti, Udaykumar R.

Subjects

*ELECTRIC transformers, *ELECTRIC inverters, *ELECTRIC potential, *ELECTRIC currents, *ELECTROSTATICS

Abstract

This paper presents a nine-level transformer-based inverter requiring only eight switches. The envisaged structure consists of two standard H-bridges fed from a single dc source. Besides, a single-phase transformer is employed to aid the process of intermediate voltage level generation. An ad-hoc pulsewidth modulation scheme based on boolean logic form equations is developed to derive the gating pulses. An effortless extension of the proposed inverter to a higher number of voltage levels is also achieved by generalizing the switching functions. Furthermore, the superior performance of the proposed topology is demonstrated through a comprehensive cost-based analysis. Finally, the validation of the proposed topology is accomplished through experiments on a down-scale prototype, and the measurement results are included. [ABSTRACT FROM AUTHOR]

Published

2018

54. New Constraint in SHE-PWM for Single-Phase Inverter Applications.

Author

Sharifzadeh, Mohammad, Vahedi, Hani, and Al-Haddad, Kamal

Subjects

*ELECTRIC inverters, *ELECTRIC potential, *ELECTRIC current converters

Abstract

This paper proposes new angles constraint for selective harmonic elimination-pulsewidth modulation (SHE)-PWM utilized in single-phase inverter applications. The proposed angles constraint naturally eliminates all triplen harmonics, whereas they conventionally appeared in all single-phase output voltages. The harmonic amplitude formula is developed based on the obtained angles constraint, and then modified single-phase SHE equations are defined to eliminate only specified low nontriplen harmonics. Therefore, more harmonics would be eliminated with the same switching frequency in modified SHE-PWM. Five-level voltage waveform has been opted to implement the introduced method, but it can be applied on all multilevel voltage waveforms such as seven-level with even number of angles. Unlike the conventional SHE technique, THD is analyzable in modified SHE to find optimum values for switching angles in order to control noneliminated harmonic amplitudes and minimize THD. Moreover, the cancellation of triplen harmonics empowers a single-phase inverter to supply nonlinear loads beside linear ones. Some experimental tests are accomplished using a single-phase five-level modified packed U-cell (MPUC) inverter. Results are discussed to prove the excellent performance of a single-phase MPUC inverter under both normal and harmonic loads and accurate elimination of determined triplen and nontriplen harmonics by applying the presented angles constraint. [ABSTRACT FROM AUTHOR]

Published

2018

55. Deadbeat Control Strategy for Circulating Current Suppression in Multiparalleled Three-Level Inverters.

Author

Xing, Xiangyang, Zhang, Chenghui, Chen, Alian, Geng, Hua, and Qin, Changwei

Subjects

*ELECTRIC inverters, *ELECTRIC currents, *ELECTRIC current converters, *COMPUTER simulation, *RELIABILITY in engineering

Abstract

This paper proposes a zero-sequence circulating current (ZSCC) control scheme for the multiparalleled three-level T-type inverters (3LT2Is). Based on the analysis with the proposed generalized model of multiparalleled 3LT2Is, it is seen that the ZSCC is influenced by the circuit parameters, duty cycles, and the circulating currents of the l th and first 3LT2I. To mitigate the circulating currents, a deadbeat control strategy for n-paralleled (n≥3) inverters is proposed, which is realized by adjusting the duty cycle of the small vectors in each PWM sampling period. Compared with the conventional PI control method, the ZSCC spike is mitigated with the proposed scheme, thus improving the quality of the output currents. Also, the reliability of the 3LT2Is system is improved because such a scheme only needs the information about the ZSCC and zero-sequence duty ratio in the l th and the first inverter. The proposed method can also be applied to the neutral-point-clamped converters. Simulation and experimental results verify the effectiveness of the theoretical analysis and the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2018

56. A Bridge Modular Switched-Capacitor-Based Multilevel Inverter With Optimized SPWM Control Method and Enhanced Power-Decoupling Ability.

Author

He, Liangzong and Cheng, Chen

Subjects

*ELECTRIC inverters, *CONVERTERS (Electronics), *ELECTRIC current converters, *POWER density, *CAPACITORS

Abstract

Microinverters operating into the single-phase grid from new energy source with low-voltage output face the challenges of efficiency bottleneck and twice-line-frequency variation. This paper proposed a multilevel inverter based on bridge modular switched-capacitor (BMSC) circuits with its superiority in conversion efficiency and power density. The topology is composed of dc–dc and dc–ac stages with independent control for each stage, aiming to improve system stability and simplify the control method. The BMSC dc–dc stage, which can be expanded to synthesize more levels, not only features multilevel voltage gain but also partially replaces the original bulk input capacitor and functions as an active energy buffer to enhance power-decoupling ability between dc and ac sides. In dc–ac stage, the control strategy of optimized unipolar frequency doubling sine-wave pulse width modulation is proposed to improve the quality of output waveform. Meanwhile, the multilevel voltage phase has been optimized to further reduce the power loss. Finally, a prototype has been built and tested. Associated with the simulation, the experimental results validate the practicability of these analyses. [ABSTRACT FROM PUBLISHER]

Published

2018

57. Short Circuit Current Characteristics Analysis and Improved Current Limiting Strategy for Three-phase Three-leg Inverter under Asymmetric Short Circuit Fault.

Author

Liang, Zhigang, Lin, Xinchun, Kang, Yong, Gao, Bofeng, and Lei, He

Subjects

*SHORT circuits, *CURRENT limiters, *ELECTRIC inverters, *ELECTRIC faults, *SIMULATION methods & models

Abstract

Three-phase three-leg inverter is one of the most popular topologies for inverters. When short-circuit fault occurs, the inverter is generally switched to the current-controlled mode from voltage-controlled mode to limit the fault currents. In this situation, the inverter becomes equivalent to a symmetric, three-phase, positive sequence current source. However, the voltage limiting may occur under asymmetrical fault. In this paper, a closed-loop model based on time-domain is originally developed as a means to investigate the fault current characteristics under asymmetrical fault. Based on the proposed model, a more intuitive insight into fault currents is presented as follows. 1) The positive sequence fundamental component of three-phase currents can still track the symmetric current references. 2) The magnitude of fault phase currents (ignoring the harmonics) will vary between 1 and $\sqrt 3 $ times of magnitude of current limiting references. Based on the conclusion, although the magnitudes of fault phase currents can be reduced by adopting smaller current limiting references, the actual magnitudes of fault phase currents will still vary in a range depending on the load impendence of healthy phase. Therefore, the reliable action of the protection devices is greatly affected and the selective protection cannot be realized. Furthermore, in order to achieve completely controllable fault currents under asymmetrical fault, two alternative current limiting strategies are presented with reverse current limiting references, and with current limiting references based on the introduced phase angle regulation. The theoretical results are validated by simulations and experimental results. [ABSTRACT FROM AUTHOR]

Published

2018

58. GaN-Based High-Frequency High-Energy Delivery Transformer Push–Pull Inverter for Ultrasound Pulsing Application.

Author

Peng, Han, Sabate, Juan, Wall, Kieran Andrew, and Glaser, John S.

Subjects

*GALLIUM nitride, *ELECTRIC transformers, *ELECTRIC inverters, *PULSE generators, *PIEZOELECTRIC transducers, *VIBRATION (Mechanics)

Abstract

Pulse generator in an ultrasound system produces electrical pulsing signals to drive piezoelectric transducer, which causes mechanical vibration of the crystals and generates sound waves. Different from conventional imaging short pulses, high-power ultrasonic system for therapeutic applications requires MHz pulses bursts of up to tens of milliseconds. The capability of switching high voltage (±90 V) at multi-MHz, delivering effective power efficiently, is crucial for practical systems. The advantages of low device loss at high switching frequency, and high power density make gallium nitride (GaN) high electron mobility transistors better devices than traditional silicon (Si) MOSFETs in such system. The GaN-based high-frequency transformer push–pull inverter presented in this paper is capable to produce high energy pulsating output with burst pulse length up to 50 ms and bipolar pulse amplitude of 180 Vpp. The maximum pulse frequency can be up to 10 MHz. The peak output power is 90 W with power density of 50.85 W/in2. The peak power for all the 128 pulser channels reaches up to 11.5 KW with average power of 192 W. This is the highest output power for pulse drivers that have been reported. A novel power transistor based RF switch circuit is also proposed in this design as the interface between image signal, high power signal, and return signal. [ABSTRACT FROM AUTHOR]

Published

2018

59. 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

60. High-Gain Single-Stage Boosting Inverter for Photovoltaic Applications.

Author

Abramovitz, Alexander, Zhao, Ben, and Smedley, Keyue Ma

Subjects

*SINGLE-stage accelerators, *ELECTRIC inverters, *PHOTOVOLTAIC power generation, *PROTOTYPES, *ENERGY consumption, *DIRECT currents

Abstract

This paper introduces a high-gain single-stage boosting inverter (SSBI) for alternative energy generation. As compared to the traditional two-stage approach, the SSBI has a simpler topology and a lower component count. One cycle control was employed to generate ac voltage output. This paper presents theoretical analysis, simulation and experimental results obtained from a 200 W prototype. The experimental results reveal that the proposed SSBI can achieve high dc input voltage boosting, good dc–ac power decoupling, good quality of ac output waveform, and good conversion efficiency. [ABSTRACT FROM AUTHOR]

Published

2016

61. Power and Voltage Balance Control of a Novel Three-Phase Solid-State Transformer Using Multilevel Cascaded H-Bridge Inverters for Microgrid Applications.

Author

Wang, Liang, Zhang, Donglai, Wang, Yi, Wu, Bin, and Athab, Hussain S.

Subjects

*ELECTRIC potential, *ELECTRIC power transmission, *ELECTRIC inverters, *ELECTRIC power distribution grids, *ELECTRIC controllers

Abstract

This paper presents a new application of power and voltage balance control schemes for the cascaded H-bridge multilevel inverter (CHMI)-based solid-state transformer (SST) topology. To reduce load on the controller and simplify modulation algorithm, a master–slave control (MSC) strategy is designed for the dual active bridge (DAB) stage. The master controller executes all control and modulation calculations, and the slave controllers manage only device switching and protection. Due to the inherent power and dc-link voltage unbalance in cascaded H-bridge-based SST, this paper presents a compensation strategy based on three-phase dq decoupled current controller. An optimum zero-sequence component is injected in the modulation scheme so that the three-phase grid currents are balanced. Furthermore, to tightly regulate the output voltage of all the DAB modules to target value, a dynamic reference voltage method is also implemented. With this proposed control method, the three-phase grid currents and dc-link voltage in each module can be simultaneously balanced. Finally, simulation and experimental results are presented to validate the performance of the controller and its application to microgrid SST. [ABSTRACT FROM PUBLISHER]

Published

2016

62. Modified DC-Bus Voltage Balancing Algorithm for a Three-Level Neutral-Point-Clamped PMSM Inverter Drive With Reduced Common-Mode Voltage.

Author

Choudhury, Abhijit, Pillay, Pragasen, and Williamson, Sheldon S.

Subjects

*ELECTRIC motors, *ELECTRIC inverters, *ELECTRIC drives, *ALGORITHMS, *CAPACITORS, *ELECTRIC capacity

Abstract

This paper presents an improved dc-link voltage balancing algorithm for a three-level neutral-point-clamped inverter by considering phase current direction. Detailed studies on the effects of change in load current direction on the dc-link capacitor voltages are presented. A maximum value of power factor is numerically derived, above which it affects the capacitor voltage balancing capability. Compared with the previously presented research work, the inputs to the space-vector pulsewidth-modulation block are the three phase currents and the difference between the two capacitor voltages. Depending on the states of the two dc-link capacitor voltages and phase current direction, redundant voltage vector sequences are selected. The selected vectors keep the capacitor voltage deviations within 5% of the total dc-link voltage. Two zero switching vectors (i.e., PPP and NNN) are also removed from all subsectors of the earlier proposed strategy, which one used to produce higher common-mode voltages. Detailed simulation and experimental results are presented in this paper for a 6.0-kW surface permanent-magnet synchronous machine. Both the simulation and experimental results show the required performance of the proposed system. [ABSTRACT FROM AUTHOR]

Published

2016

63. An Open-End Winding Four-Level Five-Phase Drive.

Author

Darijevic, Milan, Jones, Martin, and Levi, Emil

Subjects

*PULSE width modulation, *ELECTRIC potential, *WINDING machines, *ELECTRIC inverters, *INDUCTION machinery

Abstract

A four-level five-phase open-end winding (OeW) drive topology is introduced in this paper. The drive comprises a five-phase induction machine with open-end stator windings, supplied using two two-level voltage-source inverters with isolated and unequal dc-link voltages, in the ratio 2 : 1. The topology offers the advantages of a modular structure with fewer semiconductor components and has a greater potential for fault tolerance, as compared with an equivalent single-sided four-level drive. Due to the large number of switching states, development of a suitable space vector pulsewidth-modulation (PWM) method can be challenging. Hence, this paper examines the implementation of two-level-shifted carrier-based PWM methods. The effect of dead time on the drive performance is discussed, and it is shown that simultaneous PWM switching of both inverters can lead to degraded output phase voltage waveforms. Detailed analysis of this phenomenon is presented, a solution is proposed, and the modified modulation techniques are incorporated in an experimental setup, at first in conjunction with $V/f$ control. Once the proof of concept has been provided, full field-oriented control is implemented in this OeW drive topology for the first time; detailed experimental testing is conducted, and results are reported. [ABSTRACT FROM AUTHOR]

Published

2016

64. Multilevel Inverter Topologies With Reduced Device Count: A Review.

Author

Gupta, Krishna Kumar, Ranjan, Alekh, Bhatnagar, Pallavee, Sahu, Lalit Kumar, and Jain, Shailendra

Subjects

*ELECTRIC inverters, *ELECTRIC network topology, *ELECTRIC power distribution, *ELECTRIC switchgear, *COMPARATIVE studies

Abstract

Multilevel inverters have created a new wave of interest in industry and research. While the classical topologies have proved to be a viable alternative in a wide range of high-power medium-voltage applications, there has been an active interest in the evolution of newer topologies. Reduction in overall part count as compared to the classical topologies has been an important objective in the recently introduced topologies. In this paper, some of the recently proposed multilevel inverter topologies with reduced power switch count are reviewed and analyzed. The paper will serve as an introduction and an update to these topologies, both in terms of the qualitative and quantitative parameters. Also, it takes into account the challenges which arise when an attempt is made to reduce the device count. Based on a detailed comparison of these topologies as presented in this paper, appropriate multilevel solution can be arrived at for a given application. [ABSTRACT FROM AUTHOR]

Published

2016

65. A Four-Switch Three-Phase SEPIC-Based Inverter.

Author

Diab, Mohamed S., Elserougi, Ahmed, Massoud, Ahmed M., Abdel-Khalik, Ayman S., and Ahmed, Shehab

Subjects

*ELECTRIC inverters, *ENERGY dissipation, *DC-AC converters, *ENERGY conversion, *ELECTRIC utilities

Abstract

The four-switch three-phase (FSTP) inverter has been proposed as an innovative inverter design to reduce the cost, complexity, size, and switching losses of the dc–ac conversion system. Traditional FSTP inverter usually operates at half the dc input voltage; hence, the output line voltage cannot exceed this value. This paper proposes a novel design for the FSTP inverter based on the topology of the single-ended primary-inductance converter (SEPIC). The proposed topology provides pure sinusoidal output voltages with no need for output filter. Compared to traditional FSTP inverter, the proposed FSTP SEPIC inverter improves the voltage utilization factor of the input dc supply, where the proposed topology provides higher output line voltage which can be extended up to the full value of the dc input voltage. The integral sliding-mode control is used with the proposed topology to optimize its dynamics and to ensure robustness of the system during different operating conditions. Derivation of the equations describing the parameters design, components ratings, and the operation of the proposed SEPIC inverter is presented in this paper. Simulation model and experimental setup are used to validate the proposed concept. Simulations and experimental results show the effectiveness of the proposed inverter. [ABSTRACT FROM AUTHOR]

Published

2015

66. Impedance-Source Networks for Electric Power Conversion Part I: A Topological Review.

Author

Siwakoti, Yam P., Fang Zheng Peng, Blaabjerg, Frede, Poh Chiang Loh, and Town, Graham E.

Subjects

*ELECTRIC impedance, *ELECTRIC power conversion, *DIRECT currents, *ELECTRIC current rectifiers, *ELECTRIC inverters

Abstract

Impedance networks cover the entire of electric power conversion from dc (converter, rectifier), ac (inverter), to phase and frequency conversion (ac-ac) in a wide range of applications. Various converter topologies have been reported in the literature to overcome the limitations and problems of the traditional voltage source, current source as well as various classical buck-boost, unidirectional, and bidirectional converter topologies. Proper implementation of the impedance-source network with appropriate switching configurations and topologies reduces the number of power conversion stages in the system power chain, which may improve the reliability and performance of the power system. The first part of this paper provides a comprehensive review of the various impedance-source-networks-based power converters and discusses the main topologies from an application point of view. This review paper is the first of its kind with the aim of providing a “one-stop” information source and a selection guide on impedance-source networks for power conversion for researchers, designers, and application engineers. A comprehensive review of various modeling, control, and modulation techniques for the impedance-source converters/inverters will be presented in Part II. [ABSTRACT FROM AUTHOR]

Published

2015

67. Medium-Voltage Drive for Induction Machine With Multilevel Dodecagonal Voltage Space Vectors With Symmetric Triangles.

Author

Sudharshan Kaarthik, R., Gopakumar, K., Mathew, Jaison, and Undeland, Tore

Subjects

*ELECTRIC inverters, *ELECTRICAL harmonics, *PULSE width modulation, *ELECTRIC circuits, *INDUCTION motors

Abstract

Multilevel inverters with dodecagonal (12-sided polygon) voltage space vector structure have advantages, such as complete elimination of fifth and seventh harmonics, reduction in electromagnetic interference, reduction in device voltage ratings, reduction of switching frequency, extension of linear modulation range, etc., making it a viable option for high-power medium-voltage drives. This paper proposes two power circuit topologies capable of generating multilevel dodecagonal voltage space vector structure with symmetric triangles (for the first time) with minimum number of dc-link power supplies and floating capacitor H-bridges. The first power topology is composed of two hybrid cascaded five-level inverters connected to either side of an open-end winding induction machine. Each inverter consists of a three-level neutral-point-clamped inverter, which is cascaded with an isolated H-bridge making it a five-level inverter. The second topology is for a normal induction motor. Both of these circuit topologies have inherent capacitor balancing for floating H-bridges for all modulation indexes, including transient operations. The proposed topologies do not require any precharging circuitry for startup. A simple pulsewidth modulation timing calculation method for space vector modulation is also presented in this paper. Due to the symmetric arrangement of congruent triangles within the voltage space vector structure, the timing computation requires only the sampled reference values and does not require any offline computation, lookup tables, or angle computation. Experimental results for steady-state operation and transient operation are also presented to validate the proposed concept. [ABSTRACT FROM PUBLISHER]

Published

2015

68. Diode-Free T-Type Three-Level Neutral-Point-Clamped Inverter for Low-Voltage Renewable Energy System.

Author

Wang, Yong, Shi, W. W., Xie, N., and Wang, C. M.

Subjects

*DIODES, *ELECTRIC inverters, *RENEWABLE energy sources, *ELECTRIC potential, *POWER resources

Abstract

In this paper, the conventional I- and T-type three-level neutral-point-clamped (3L-NPC) inverter for low-voltage renewable energy systems is first investigated. Literature research shows that the T-type inverter improves I-type's insulated-gate bipolar transistor (IGBT) $+$ IGBT current paths. However, the IGBT $+$ diode paths are the same. The calculation in this paper further reveals that the IGBT $+$ diode current paths dominate the conduction losses and even the whole semiconductor losses. Based on the aforementioned recognitions, a novel T-type inverter is presented as an alternative to be applied in the low-voltage renewable energy systems. In the proposed 3L-NPC, four CoolMosfets replace the IGBT $+$ diode middle bidirectional switch. In the proposed topology, there is no diode involved in the current path supposing the unity power factor. In this way, the conduction loss is expected to be reduced compared with that from the conventional T-type 3L-NPC, particularly in the low and medium power ranges. [ABSTRACT FROM PUBLISHER]

Published

2014

69. Comparison and Analysis of Single-Phase Transformerless Grid-Connected PV Inverters.

Author

Freddy, Tan Kheng Suan, Rahim, Nasrudin A., Wooi-Ping Hew, and Hang Seng Che

Subjects

*ELECTRIC transformers, *ELECTRIC inverters, *PHOTOVOLTAIC power systems, *ELECTRIC potential, *STRAY currents, *GALVANIC isolation

Abstract

Leakage current minimization is one of the most important considerations in transformerless photovoltaic (PV) inverters. In the past, various transformerless PV inverter topologies have been introduced, with leakage current minimized by the means of galvanic isolation and common-mode voltage (CMV) clamping. The galvanic isolation can be achieved via dc-decoupling or ac-decoupling, for isolation on the dc- or ac-side of the inverter, respectively. It has been shown that the latter provides lower losses due to the reduced switch count in conduction path. Nevertheless, leakage current cannot be simply eliminated by galvanic isolation and modulation techniques, due to the presence of switches' junction capacitances and resonant circuit effects. Hence, CMV clamping is used in some topologies to completely eliminate the leakage current. In this paper, several recently proposed transformerless PV inverters with different galvanic isolation methods and CMV clamping technique are analyzed and compared. A simple modified H-bridge zero-voltage state rectifier is also proposed, to combine the benefits of the low-loss ac-decoupling method and the complete leakage current elimination of the CMV clamping method. The performances of different topologies, in terms of CMV, leakage current, total harmonic distortion, losses and efficiencies are compared. The analyses are done theoretically and via simulation studies, and further validated with experimental results. This paper is helpful for the researchers to choose the appropriate topology for transformerless PV applications and to provide the design principles in terms of common-mode behavior and efficiency. [ABSTRACT FROM AUTHOR]

Published

2014

70. Combined Bidirectional Buck–Boost DC–DC Chopper-Mode Inverters With High-Frequency Link.

Author

Chen, Daolian and Chen, Sheng

Subjects

*ELECTRIC inverters, *CHOPPER circuits, *SWITCHING circuits, *CLAMPING circuits, *TOPOLOGY

Abstract

A circuit configuration, a circuit topological family, a buck-mode active clamped circuit, and an instantaneous output voltage feedback control strategy of combined bidirectional buck–boost dc–dc chopper-mode inverter with high-frequency (HF) link (HFL) were proposed and fully investigated in this paper. The steady principle characteristic and the design criteria for the key circuit parameters were given in this paper. The circuit configuration is composed of two identical isolated bidirectional buck–boost dc–dc choppers with the same input and output filters. These two choppers in parallel at input end and in series at output end generate unipolarity sinusoidal pulsewidth modulation current waveforms with positive and negative half low-frequency cycles separately. The circuit topological family includes four circuit topologies, such as one-transistor mode. Taking the one-transistor mode circuit topology as an example, the 750VA48VDC/220V50HzAC prototype is designed and implemented. The theoretical analysis and principle test show the inverters have excellent performance. [ABSTRACT FROM PUBLISHER]

Published

2014

71. A New Cascaded Multilevel Inverter Topology with Galvanic Isolation.

Author

Hasan, Md Mubashwar, Abu-Siada, Ahmed, Islam, Syed Mofizul, and Dahidah, Mohamed S. A.

Subjects

*ELECTRIC inverters, *GALVANIC isolation, *ELECTRIC potential, *TOPOLOGY, *MAGNETIC fields

Abstract

This paper presents a new compact three-phase cascaded multilevel inverter (CMLI) topology with reduced device count and high-frequency magnetic link. The proposed topology overcomes the predominant limitation of separate dc power supplies, which CMLI always require. The high-frequency magnetic link also provides a galvanic isolation between the input and output sides of the inverter, which is essential for various grid-connected applications. The proposed topology utilizes an asymmetric inverter configuration that consists of cascaded H-bridge cells and a conventional three-phase two-level inverter. A toroidal core is employed for the high-frequency magnetic link to ensure compact size and high-power density. Compared with counterpart CMLI topologies available in literature, the proposed inverter has the advantage of utilizing the least number of power electronic components without compromising the overall performance, particularly when a high number of output voltage levels is required. The feasibility of the proposed inverter is confirmed through extensive simulation and experimentally validated studies. [ABSTRACT FROM AUTHOR]

Published

2018

72. Power Decoupling for Single-Phase PV System Using $\acute{\mathrm{C}}$uk Derived Microinverter.

Author

Jamatia, Anindita, Gautam, Vasav, and Sensarma, Parthasarathi

Subjects

*ELECTRIC inverters, *EARTH currents, *STRAY currents, *PHOTOVOLTAIC power systems, *ELECTROLYTIC capacitors, *CAPACITORS, *DYNAMIC models

Abstract

This paper reports an elegant approach to address two major challenges of transformerless grid-connected microinverters, common-mode earth leakage current and double-frequency power pulsation across the photovoltaic (PV) terminal. The proposed solution uses an embedded decoupling capacitor in a doubly grounded boost–buck ( $\acute{\mathrm{C}}$ uk) derived topology. An intelligent switching scheme ensures that a large swing of the decoupling capacitor voltage is easily accommodated. Thus, film capacitors can be used instead of electrolytic capacitors, which helps increase equipment lifetime. Details of circuit operation are provided along with dynamic modeling and controller design for close-loop operation. Simulation and experimental results are presented for performance validation of the microinverter. [ABSTRACT FROM AUTHOR]

Published

2018

73. Multi-Input Switched-Capacitor Multilevel Inverter for High-Frequency AC Power Distribution.

Author

Raman, S. Raghu, Cheng, Ka Wai Eric, and Ye, Yuanmao

Subjects

*MULTI-infarct dementia, *CAPACITOR switching, *ELECTRIC power distribution, *ELECTRIC inverters, *PROBLEM solving

Abstract

This paper proposes a switched-capacitor multilevel inverter for high-frequency ac power distribution systems. The proposed topology produces a staircase waveform with higher number of output levels employing fewer components compared to several existing switched-capacitor multilevel inverters in the literature. This topology is beneficial where asymmetric dc voltage sources are available, e.g., in case of renewable energy farms based ac microgrids and modern electric vehicles. Utilizing the available dc sources as inputs for a single inverter solves the major problem of connecting several inverters in parallel. Additionally, the need to stack voltage sources, like batteries or supercapacitors, in series which demand charge equalization algorithms, are eliminated as the voltage sources employed share a common ground. The inverter inherently solves the problem of capacitor voltage balancing as each capacitor is charged to the value equal to one of the input voltage every cycle. State analysis, losses, and the selection of capacitance are examined. Simulation and experimental results at different distribution frequencies, power levels, and output harmonic content are provided to demonstrate the feasibility of the proposed multilevel inverter topology. [ABSTRACT FROM PUBLISHER]

Published

2018

74. New Switching Strategy for Single-Mode Operation of a Single-Stage Buck?Boost Inverter.

Author

Kumar, Ashok and Sensarma, Parthasarathi

Subjects

*ELECTRIC inverters, *TOPOLOGY, *ELECTRIC potential, *PROTOTYPES, *POLARITY (Physics)

Abstract

Generally, single-stage buck–boost inverters consist of distinct circuits operating individually in buck/boost or positive/negative modes, the latter definitely leading to crossover distortion in the output current. This paper proposes a switching strategy that changes the bimodal operation of a single-stage buck–boost topology to a single-mode inverter. This is due to the consequent voltage gain that ensures that the output voltage polarity, apart from its magnitude, is an exclusive function of the duty ratio. Operational principle and salient hardware design are explained with the help of equivalent circuits. Details about the dynamic model are presented, based on which controller design is carried out for both stand-alone and grid-connected operation. Experimental results obtained from a 300-W, 110-V laboratory prototype are presented to validate the performance of the proposed switching strategy. [ABSTRACT FROM PUBLISHER]

Published

2018

75. Single-Phase Modified Quasi-Z-Source Cascaded Hybrid Five-Level Inverter.

Author

Ho, Anh-Vu and Chun, Tae-Won

Subjects

*ELECTRIC inverters, *VOLTAGE control, *ELECTRIC impedance, *ELECTRONIC modulation, *SWITCHING theory

Abstract

This paper proposes the combination of a novel modified quasi-Z-source (MqZS) inverter with a single-phase symmetrical hybrid three-level inverter in order to boost the inverter three-level output voltage. The proposed single-phase MqZS hybrid three-level inverter provides a higher boost ability and reduces the number of inductors in the source impedance, compared with both the single-phase three-level neural-point clamped quasi-Z-source inverter and the single-phase quasi-Z-source cascaded multilevel inverter. Additionally, it can be extended to obtain the nine-level output voltage by cascading two three-level pulse width modulation switching cells with a separate MqZS and a dc source, which herein is called a single-phase MqZS cascaded hybrid five-level inverter (MqZS-CHI). A modified modulation technique based on an alternative phase opposition disposition scheme is suggested to effectively control the shoot-through state for boosting the dc-link voltage and balancing the two series capacitor voltages of the MqZS. The performances of both the proposed MqZS-CHI and the modulation techniques are verified through simulation and experimental results. [ABSTRACT FROM PUBLISHER]

Published

2018

76. Operation and Control of a Nine-Level Modified ANPC Inverter Topology With Reduced Part Count for Grid-Connected Applications.

Author

Sandeep, N. and Yaragatti, Udaykumar R.

Subjects

*ELECTRIC inverters, *TOPOLOGY, *VOLTAGE control, *CAPACITORS, *ELECTRIC switchgear, *POWER supply quality, *RENEWABLE energy sources

Abstract

This paper presents a nine-level active-neutral-point-clamped (ANPC) based multilevel inverter (MLI) topology for grid-connected applications requiring only ten switches. The envisaged structure comprises two parts, namely five-level ANPC unit, and a two-level converter leg whose midpoint is used as another ac terminal. An ad hoc switching state redundancy based modulation strategy is used to ensure that the voltage across the flying capacitor is tightly balanced and is implemented using a look-up table further simplifies the control complexity. The performance and effectiveness of the proposed topology with its control scheme are validated through simulations and experimental tests. Comparison with other MLIs is included to highlight the merits of the proposed topology. From the results, it will be shown that the proposed inverter requires the least part count as compared to other topologies with the same performance and output quality. [ABSTRACT FROM PUBLISHER]

Published

2018

77. A Symmetrical Cascaded Compact-Module Multilevel Inverter (CCM-MLI) With Pulsewidth Modulation.

Author

Lee, Sze Sing, Heng, Yeh En, Sidorov, Michail, and Idris, Nik Rumzi Nik

Subjects

*ELECTRIC inverters, *PULSE width modulation transformers, *TOPOLOGY, *SWITCHING circuits, *VOLTAGE control

Abstract

Cascaded H-bridge (CHB) multilevel inverters (MLIs) have been widely used for power electronics systems. While high-voltage blocking across power switches is not a constraint for low voltage applications, the research trend has been oriented to the design of more compact module topologies as an alternative for CHB. Despite the generation of more voltage levels with reduced switch count, the existing module topologies in recent literature take no account of the freewheeling current path during dead-time, thus, inducing multistep jumps in voltage levels and giving rise to undesirable voltage spikes. Addressing this concern, this paper proposes two symmetrical compact-module topologies for cascaded MLI, where freewheeling current path during dead-time is provided for smooth transition between voltage levels to prevent voltage spikes. The proposed 7-level and 13-level compact-modules demonstrated low number of conducting switches for all voltage levels. Comprehensive analysis and comparison with the latest module topologies are conducted. To validate the operation of the proposed compact-module topologies, simulation and experimental results are presented. [ABSTRACT FROM PUBLISHER]

Published

2018

78. Three-Phase Transformerless Shunt Active Power Filter With Reduced Switch Count for Harmonic Compensation in Grid-Connected Applications.

Author

Tareen, Wajahat Ullah Khan and Mekhielf, Saad

Subjects

*ELECTRIC transformers, *NONLINEAR theories, *ELECTRICAL load, *ELECTRIC power distribution grids, *ELECTRIC network topology, *ELECTRIC inverters

Abstract

Shunt active power filter (SAPF) is the preeminent solution against nonlinear loads, current harmonics, and power quality problems. APF topologies for harmonic compensation use numerous high-power rating components and are therefore disadvantageous. Hybrid topologies combining low-power rating APF with passive filters are used to reduce the power rating of voltage source inverter (VSI). Hybrid APF topologies for high-power rating systems use a transformer with large numbers of passive components. In this paper, a novel four-switch two-leg VSI topology for a three-phase SAPF is proposed for reducing the system cost and size. The proposed topology comprises a two-arm bridge structure, four switches, coupling inductors, and sets of LC PFs. The third leg of the three-phase VSI is removed by eliminating the set of power switching devices, thereby directly connecting the phase with the negative terminals of the dc-link capacitor. The proposed topology enhances the harmonic compensation capability and provides complete reactive power compensation compared with conventional APF topologies. The new experimental prototype is tested in the laboratory to verify the results in terms of total harmonic distortion, balanced supply current, and harmonic compensation, following the IEEE-519 standard. [ABSTRACT FROM AUTHOR]

Published

2018

79. Grid-Connected Symmetrical Cascaded Multilevel Converter for Power Quality Improvement.

Author

Mortezaei, Ali, Simoes, Marcelo Godoy, Busarello, Tiago Davi Curi, Marafao, Fernando Pinhabel, and Al-Durra, Ahmed

Subjects

*ELECTRIC inverters, *DIRECT current power transmission, *MICROGRIDS, *CASCADE converters, *EXPERIMENTS

Abstract

This paper discusses the use of a cascaded multilevel converter for flexible power conditioning in smart-grid applications. The main feature of the proposed scheme is the use of independent dc links with reduced voltages, which makes such a topology an ideal candidate for medium- and high-power applications with increased reliability. The developed control strategy regulates independent dc-link voltages in each H-bridge cell, and allows the selective and flexible compensation of disturbing currents under a variety of voltage conditions without requiring any reference frame transformation. The selective control strategies are based on the decompositions proposed in the conservative power theory, which result in several current-related terms associated with specific load characteristics. These current components are independent of each other and may be used to define different compensation strategies, which can be selective in minimizing particular effects of disturbing loads. Experimental results are provided to validate the possibilities and performance of the proposed control strategies, considering ideal and deteriorated voltage conditions. [ABSTRACT FROM PUBLISHER]

Published

2018

80. A New Soft-Switching Topology for Switched Inductor High Gain Boost.

Author

Yao, Tong, Ayyanar, Rajapandian, and Nan, Chenhao

Subjects

*ELECTRIC inductors, *SWITCHING circuits, *DC-to-DC converters, *ELECTROMAGNETIC interference, *PHOTOVOLTAIC power systems, *ELECTRIC inverters, *COMPUTER simulation

Abstract

This paper proposes a new high-gain soft-switching dc–dc topology based on a switched inductor boost converter (SIBC). A conventional SIBC as a high gain boost topology has the issues of high conduction loss in switching diodes and high switching loss in the main switches. Also, it has severe electromagnetic interference (EMI) issue due to high-frequency ringing formed by parasitic inductance and diode junction capacitors. The new topology is derived with the objective of achieving zero voltage switching (ZVS) turn on of the main switch. Instead of adding extra active clamp zero voltage transition (ZVT) path at the switching node, the proposed topology augments the auxiliary ZVT path to the switching diode path. This is achieved by replacing the switching diodes with synchronous switches. The new topology can achieve soft switching for all the switches and alleviate the EMI issue. All the diodes achieve zero current switching (ZCS) turn off without reverse recovery. Auxiliary switches have ZCS turn on and ZVS turn off, and the main switches have ZVS turn on. The soft-switching SIBC also reduces the conduction loss in the switching diodes. A numerical simulation in PLECS and a prototype hardware are built corresponding to a micro-inverter application with 100 kHz switching frequency. Peak power conversion efficiency of 94.76% is achieved in the hardware prototype with Si devices. [ABSTRACT FROM PUBLISHER]

Published

2018

81. Resolving Practical Design Issues in a Single-Phase Grid-Connected GaN-FET-Based Differential-Mode Inverter.

Author

Kulkarni, Abhijit, Gupta, Ankit, and Mazumder, Sudip K.

Subjects

*FIELD-effect transistors, *MICROGRIDS, *GALLIUM nitride, *ELECTRIC inverters, *PHOTOVOLTAIC power systems, *POWER transformers, *VOLTAGE control

Abstract

Microinverters for grid-connected photovoltaic (PV) power conversion systems often require voltage boost due to the low dc voltage of the PV panels. A high-frequency (HF) transformer-isolated differential-mode Ćuk inverter (DMCI) is an attractive topology due to its inherent voltage boost capability and high power density. One of the significant operational issue of the DMCI addressed in this paper is the presence of lower order harmonic distortion in the injected grid current. It is shown that lower order odd and even harmonic voltages are generated with this topology. This problem is accentuated due to the low damping offered by the grid to harmonic voltages. A systematic low-complexity control design is proposed to address this issue. It is shown experimentally that the DMCI operates stably with effective attenuation of the lower order harmonics using the proposed design. Practical operational issues of the DMCI with fast switching GaN field-effect transistor (FET) devices are analyzed and solutions are proposed. It is shown that there can be significant HF noise generation in the DMCI with a frequency range higher than the switching frequency. Practical solutions for resolving HF issues using a combination of circuit layout design and additional passive components are proposed and validated. All of the experimental results are demonstrated on a 500-W GaN-FET-based microinverter prototype. [ABSTRACT FROM PUBLISHER]

Published

2018

82. Switching Loss Reduction in the Three-Phase Quasi-Z-Source Inverters Utilizing Modified Space Vector Modulation Strategies.

Author

Abdelhakim, Ahmed, Davari, Pooya, Blaabjerg, Frede, and Mattavelli, Paolo

Subjects

*ELECTRIC inverters, *SWITCHING circuits, *LOGIC circuits, *PHASE modulation, *ELECTRIC impedance

Abstract

Several single-stage topologies have been introduced since kicking off the three-phase Z-source inverter (ZSI), and among these topologies, the quasi-ZSI (qZSI) is the most common one due to its simple structure and continuous input current. Furthermore, different modulation strategies, utilizing multiple reference signals, have been developed as well. However, prior art modulation methods have some demerits, such as the complexity of generating the gate signals, the increased number of switch commutations with continuous commutation at high current level during the entire fundamental cycle, and the multiple commutations at a time. Hence, this paper proposes two modified space vector modulation strategies, aimed at the reduction of the qZSI number of switch commutations at high current level for shorter periods during the fundamental cycle, i.e., reducing the switching loss, simplifying the generation of the gate signals by utilizing only three reference signals, and achieving a single-switch commutation at a time. These modulation strategies are analyzed and compared to the conventional ones, where a reduced-scale 1-kVA three-phase qZSI is designed and simulated using these different modulation strategies. Finally, the 1-kVA three-phase qZSI is implemented experimentally to validate the performance of the proposed modulation strategies and verify the reported analysis. [ABSTRACT FROM PUBLISHER]

Published

2018

83. A Single-Switch Quadratic Buck?Boost Converter With Continuous Input Port Current and Continuous Output Port Current.

Author

Zhang, Neng, Zhang, Guidong, See, Khay Wai, and Zhang, Bo

Subjects

*CONVERTERS (Electronics), *ELECTRIC inverters, *VOLTAGE control, *ELECTRIC power conversion, *CAPACITORS

Abstract

A single-switch quadratic buck–boost converter with continuous input port current and continuous output port current is proposed in this paper. Compared with the traditional buck-boost converter, the proposed converter can obtain a wider range of the voltage conversion ratio with the same duty cycle. Moreover, the proposed converter can operate with continuous input port current and continuous output port current compared to the existing counterparts with inherently discontinuous input port current and discontinuous output port current. The operating principle and steady-state performance of the proposed converter under continuous inductor current mode is analyzed in detail. Then, the comparison between the proposed converter and the existing quadratic buck–boost converters has been conducted to demonstrate the unique features of the proposed one. Finally, experimental results from a prototype built in the lab are recorded to verify the effectiveness and validity of the proposed quadratic buck–boost converter. [ABSTRACT FROM PUBLISHER]

Published

2018

84. An Improved Three-Phase Five-Level Inverter Topology With Reduced Number of Switching Power Devices.

Author

Hota, Arpan, Jain, Sachin, and Agarwal, Vivek

Subjects

*ELECTRIC inverters, *ELECTRIC current converters, *CONVERTERS (Electronics), *ELECTRIC potential, *SWITCHING power supplies

Abstract

This paper presents an optimized topology of 3-$\phi$ , multilevel inverter (MLI) configuration for five or higher level operation with reduced switch count. The proposed solution consists of two basic units (BUs) of multilevel converter and a T-structured 3-level inverter (3-LI). Both BUs are equally shared by the three phases maintaining symmetry among the phases. Moreover, for a higher level operation of the proposed MLI, the modifications required are at two BUs only and not at three legs of the inverter. It further helps in reducing the requirement of extra components for higher level operation compared to the conventional solutions. Furthermore, the topology also has the benefits of reduced switching and conduction loss. An algorithm is also devised to generate the switching pulses for the BUs and the 3-LI, using a carrier-based space vector modulation technique. Presented topology is compared with other existing topologies to prove its advantage. All the details regarding the operating modes and pulse width modulation techniques employed for the proposed system are given and supported by the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2018

85. 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

86. 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

87. An Isolated High-Frequency Link Microinverter Operated with Secondary-Side Modulation for Efficiency Improvement.

Author

Kummari, Nareshkumar, Chakraborty, Shiladri, and Chattopadhyay, Souvik

Subjects

*ELECTRIC inverters, *PULSE width modulation, *CYCLOCONVERTERS, *STRAY currents, *ELECTRIC inductance, *ZERO voltage switching

Abstract

This paper discusses the operation of a single-stage, isolated, high-frequency ac-link-based single-phase dc–ac converter, suitable for photovoltaic microinverter applications, controlled using phase modulation of the secondary-side cycloconverter devices. A detailed analysis is presented explaining the impact of prominent circuit nonidealities such as device capacitance and transformer leakage inductance on circuit behavior. The proposed extended-dead-time based modulation scheme helps in achieving zero-voltage-switching of the primary devices over the entire line cycle of the ac output and also offers the benefit of reduced transformer rms current due to absence of circulating current in the zero state. A flyback-based regenerative clamp circuit is used for mitigating voltage spikes on the secondary devices arising due to leakage inductance induced oscillations. A generic commutation strategy is also discussed, which makes operation with nonunity power factor loads also possible. Experimental results on a 260-W laboratory prototype under different load conditions are presented to illustrate the discussed principles and highlight the performance improvements. [ABSTRACT FROM PUBLISHER]

Published

2018

88. New Method for Common Mode Voltage Cancellation in Motor Drives: Concept, Realization, and Asymmetry Influence.

Author

Han, Di, Lee, Woongkul, Li, Silong, and Sarlioglu, Bulent

Subjects

*ELECTRIC motors, *VOLTAGE control, *PULSE width modulation, *ELECTRIC inverters, *STRAY currents, *GALLIUM nitride

Abstract

This paper introduces a new concept of common mode voltage cancellation for pulse width modulated motor drives, aiming at solving issues such as ground leakage current, common mode electromagnetic interference, and bearing current. The balanced inverter topology and dual-winding stator configuration are proposed as a practical realization. Implementation considerations on the influence of circuit asymmetry are also investigated. Finally, a gallium nitride HEMT based induction motor drive prototype is built and tested to evaluate the performance of the cancellation concept in a practical situation. [ABSTRACT FROM AUTHOR]

Published

2018

89. A Square T-Type (ST-Type) Module for Asymmetrical Multilevel Inverters.

Author

Samadaei, Emad, Sheikholeslami, Abdolreza, Gholamian, Sayyed Asghar, and Adabi, Jafar

Subjects

*ELECTRIC inverters, *SEMICONDUCTORS, *DIRECT current circuits, *MODULAR forms, *HARMONIC distortion (Physics)

Abstract

This paper introduces a new module for asymmetrical multilevel inverters with a low number of components. The module is a square combination of two back-to-back T-type inverters and some other switches. A square T-type module produces 17 levels by 12 switches and 4 unequal dc sources (two 3VDC and two 1V DC). Also, it can be extended as a cascade connection in two strategies to achieve more levels. The module and its cascade connection are suitable for the applications in several dc sources systems such as photovoltaic farms, which lead to a modular topology with more voltage levels at higher voltages. Inherent creation of the negative voltage levels without any additional circuit (such as H-bridge circuit) is one of the main features of the proposed module. The low total harmonic distortion of the output voltage/current and low number of semiconductors are among the other advantages of the proposed module. A nearest level control method as a switching technique is used to produce high quality output voltage with lower harmonic contents. Simulations have been performed in MATLAB/Simulink and a prototype is implemented in the Power Electronics Laboratory; both the simulation and experimental results show a good performance. [ABSTRACT FROM AUTHOR]

Published

2018

90. Modified Single-Phase Single-Stage Grid-Tied Flying Inductor Inverter With MPPT and Suppressed Leakage Current.

Author

Tofigh Azary, Mehdi, Sabahi, Mehran, Babaei, Ebrahim, and Abbasi Aghdam Meinagh, Farhad

Subjects

*ELECTRIC inverters, *STRAY currents, *PHOTOVOLTAIC cells, *PHOTOVOLTAIC power generation, *MAXIMUM power point trackers

Abstract

In this paper, an improved transformerless single-phase single-stage grid-tied flying inductor inverter is presented. The negative terminal of the photovoltaic (PV) array is grounded in the improved topology, which increases reliability and suppresses the leakage current. The proposed topology has buck–boost capability without increasing the number of required components and has a high efficiency. An improved control algorithm for proper operation of the proposed topology which decreases switching losses has been investigated. Moreover, a perturbation and observation maximum power point tracking (MPPT) algorithm has been adapted to the proposed inverter, which does not utilize proportional–integral (PI) controllers, for the purpose of the MPPT. Furthermore, a design procedure of the passive elements of the converter based on the corresponding operating has been demonstrated. Simulation in MATLAB Simulink plus an experimental prototype is developed to reconfirm the designed results. Finally, a comparison study has been investigated for better clarification of the advantages and disadvantages of the proposed inverter. [ABSTRACT FROM PUBLISHER]

Published

2018

91. A Reduced Switching Loss Technique Based on Generalized Scalar PWM for Nine-Switch Inverters.

Author

de Andrade, Felipe Correa, Bradaschia, Fabricio, Limongi, Leonardo Rodrigues, and Cavalcanti, Marcelo Cabral

Subjects

*DC-AC converters, *ELECTRIC switchgear, *PULSE width modulation, *POWER electronics, *ENERGY conversion, *ELECTRIC inverters

Abstract

For three-phase dual-output dc–ac conversion systems, the nine-switch inverter is one of the most versatile available topologies. Despite some disadvantages, recent studies show that the nine-switch inverter achieves efficiency values equivalent to or higher than its 12-switch counterpart, when operating in certain ranges of the modulation index and displacement angles. The use of proper pulse width modulation techniques is able to increase the efficiency even more, as well as to equalize the loss distribution among the switches, favoring an effective and low-cost thermal design. The available pulse width modulation techniques are complex and do not explore the full capacity of the nine-switch inverter to reduce its losses. For this reason, this paper proposes an unrestricted generalized scalar pulse width modulation for nine-switch inverters. Based on this new generalization, a current peak tracking technique is also proposed, achieving small average number of switchings and the highest overall efficiency when compared with other techniques, likewise a more balanced loss distribution among the switches. Experimental results are carried out to demonstrate the validity of the new generalization and the effectiveness of the proposed technique in reducing the switching losses. [ABSTRACT FROM PUBLISHER]

Published

2018

92. Commutation Torque Ripple Reduction in the BLDC Motor Using Modified SEPIC and Three-Level NPC Inverter.

Author

Viswanathan, Vaiyapuri and Seenithangom, Jeevananthan

Subjects

*BRUSHLESS direct current electric motors, *ELECTRIC inverters, *VOLTAGE control, *TORQUE control, *ELECTRIC inductors

Abstract

This paper presents a new power converter topology to suppress the torque ripple due to the phase current commutation of a brushless dc motor (BLDCM) drive system. A combination of a three-level diode clamped multilevel inverter (3-level DCMLI), a modified single-ended primary-inductor converter (SEPIC), and a dc-bus voltage selector circuit is employed in the proposed torque ripple suppression circuit. For efficient suppression of torque pulsation, the dc-bus voltage selector circuit is used to apply the regulated dc-bus voltage from the modified SEPIC during the commutation interval. In order to further mitigate the torque ripple pulsation, the 3-level DCMLI is used in the proposed circuit. Finally, simulation and experimental results show that the proposed topology is an attractive option to reduce the commutation torque ripple significantly at low- and high-speed applications. [ABSTRACT FROM PUBLISHER]

Published

2018

93. A Self-Balanced Step-Up Multilevel Inverter Based on Switched-Capacitor Structure.

Author

Taghvaie, Amir, Adabi, Jafar, and Rezanejad, Mohammad

Subjects

*ELECTRIC inverters, *SWITCHED capacitor circuits, *BIPOLAR integrated circuits, *VOLTAGE control, *HARMONIC distortion (Physics)

Abstract

In this paper, a dc to ac converter with the ability of voltage increasing is presented. This inverter is designed in a way that just one dc source is used. Also, by using power storage technique and with combining charged capacitors and dc source in series form, output voltage levels can be increased. This inverter is in a modular structure and has the ability of capacitor's voltage self-balancing. H-bridge inverter was not used at the end of the proposed converter and all elements tolerate a voltage stress equal to the amount of input dc source. This leads to remarkable decrease of total standing voltage and peak inverse voltage. Other advantage of the proposed inverter is its potentiality of performance in high-frequency applications. The modular form of the proposed inverter provides the potentiality of extension to higher voltage levels and eases the maintenance. Moreover, considering to the fact that the stress of all components of the suggested inverter is equal to the input source, the performance in high voltage is added to the characteristics of the proposed inverter. The nine-level structure of the proposed inverter is simulated and laboratory test is carried out for the verification of its performance. [ABSTRACT FROM PUBLISHER]

Published

2018

94. Novel Cascaded Switched-Diode Multilevel Inverter for Renewable Energy Integration.

Author

Wang, Lei, Wu, Q. H., and Tang, Wenhu

Subjects

*ELECTRIC inverters, *RENEWABLE energy sources, *DIODES

Abstract

In this paper, a new topology of two-stage cascaded switched-diode (CSD) multilevel inverter is proposed for medium-voltage renewable energy integration. First, it aims to reduce the number of switches along with its gate drivers. Thus, the installation space and cost of a multilevel inverter are reduced. The spike removal switch added in the first stage of the inverter provides a flowing path for the reverse load current, and as a result, high voltage spikes occurring at the base of the stepped output voltage based upon conventional CSD multilevel inverter topologies are removed. Moreover, to resolve the problems related to dc source fluctuations of multilevel inverter used for renewable energy integration, the clock phase-shifting (CPS) one-cycle control (OCC) is developed to control the two-stage CSD multilevel inverter. By shifting the clock pulse phase of every cascaded unit, the staircase-like output voltage waveforms are obtained and a strong suppression ability against fluctuations in dc sources is achieved. Simulation and experimental results are discussed to verify the feasibility and performances of the two-stage CSD multilevel inverter controlled by the CPS OCC method. [ABSTRACT FROM AUTHOR]

Published

2017

95. Operation and Control of an Improved Hybrid Nine-Level Inverter.

Author

Sandeep, N. and Yaragatti, Udaykumar R.

Subjects

*ELECTRIC inverters, *CAPACITORS, *WIND turbines, *POWER resources, *ELECTRICAL engineering

Abstract

This paper proposes a new nine-level inverter for medium- and high-power applications. The proposed topology comprises of a three-level (3L) active neutral-point-clamped (ANPC) inverter connected in series with a floating capacitor (FC) fed H-bridge. Besides, two additional switches operating at line frequency are appended across the dc link of the 3L ANPC structure. Compared with conventional hybrid cascaded inverters, the primary advantage of this addition is doubling of the resulting root mean square output voltage. This amelioration is achieved while preserving the standard 3L ANPC and H-bridge structures with minimum topological modification. A simple logic-gate-based voltage balancing scheme is developed to regulate the FC voltage. The proposed voltage balancing method is independent of load power factor, inverter modulation index, and can balance the voltage across FC instantaneously. The step-by-step formulation of logical expressions for the generation of gating pulses is deliberated in detail and can be generalized for any $n$-level inverter. Further, simulation results as well as the experimental measurements obtained from the laboratory prototype are presented to validate the effectiveness and practicability of the proposed configuration. Finally, the notable merits of the proposed inverter over the prior art topologies is established through a comprehensive comparative study. [ABSTRACT FROM PUBLISHER]

Published

2017

96. Implementation of Active NPC Circuits in Transformer-Less Single-Phase Inverter With Low Leakage Current.

Author

Zhou, Liwei, Gao, Feng, and Xu, Tao

Subjects

*ELECTRIC transformers, *ELECTRIC inverters, *STRAY currents, *PHOTOVOLTAIC power systems, *ELECTRICAL engineering

Abstract

Transformer-less grid-connected photovoltaic (PV) systems face the challenge of keeping low leakage current due to their nonisolation configurations. To better attenuate the leakage current in the single-phase systems, a few neutral-point-clamped (NPC) topologies have been proposed. This paper further proposes an active NPC method by only employing one additional switch to connect the midpoint dc link and the freewheeling circuit of traditional single-phase PV inverters. After exploring the operational principles of freewheeling circuits, the construction method and the implementation of active NPC circuits in transformer-less single-phase inverters are elaborated in detail. Since only the leakage current flows through the additional NPC switch, the presented single-phase NPC inverters could still maintain the high operational efficiency with the further attenuated leakage current. The experimental results verified the theoretical findings. [ABSTRACT FROM PUBLISHER]

Published

2017

97. 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

98. An Improved Zero-Current-Switching Single-Phase Transformerless PV H6 Inverter With Switching Loss-Free.

Author

Xiao, Hua F., Zhang, Li, and Li, Yanqing

Subjects

*ELECTRIC inverters, *ELECTRIC transformers, *RESONANT inverters, *DIODES, *VACUUM tubes

Abstract

In this paper, a switching loss-free (SLF) concept for the first six-switches H-bridge inverter (H6-I) topology is proposed. SLF means that its switches are able to operate with soft turn-on and turn-off transitions. In order to implement the SLF goal, a new resonance-trajectory is proposed. Compared with the zero-current-transition H6-I (ZCT-H6-I) topology published in previous literature, the proposed resonance-trajectory can precisely compensate for losses of resonant tanks every switching period. With this intention, an implementing circuit is structured based on the H6-I topology, and its detailed operation principle and performance characteristics are analyzed. As a result, all active switches of the new circuit are switched under zero-current turn-on and zero-current turn-off conditions. Also, the reverse recovery problem of freewheeling diodes is alleviated owing to the zero-current turn-off property of diodes. The SLF target is realized in theory. Finally, experimental results from a 1 kW prototype at 50 kHz switching frequency are provided to verify the effectiveness of the proposed SLF concept in practice. Specifically, the conversion efficiency of the new circuit is over 95% in a wide load range, and there is roughly a 1.5% efficiency improvement compared with the hard-switching H6-I topology. [ABSTRACT FROM PUBLISHER]

Published

2017

99. A Modified T-Structured Three-Level Inverter Configuration Optimized With Respect to PWM Strategy Used for Common-Mode Voltage Elimination.

Author

Hota, Arpan, Jain, Sachin, and Agarwal, Vivek

Subjects

*ELECTROMAGNETIC interference, *ELECTRIC potential, *ELECTRIC inverters, *PULSE width modulation transformers, *DIRECT currents

Abstract

This paper presents an optimized topology for a \text3-\phi three-level inverter with complete elimination of common-mode voltage (CMV). The proposed multilevel inverter (MLI) configuration is realized by modifying a T-structure \text3-\phi inverter. The proposed configuration is an optimized solution with respect to the pulse-width modulation strategy used for CMV elimination. The given three-level inverter structure uses only 16 power semiconductor switches, which is much lower than the existing configurations. A reduced number of power semiconductor devices results in a diminished number of driver circuits, less installation space, and low cost. Further, due to the complete elimination of CMV, the proposed MLI is free from issues such as electromagnetic interference and leakage current with a reduction in filter requirement. The presented topology is also compared with other existing topologies to prove its advantage. It is an optimized solution with respect to the dc bus voltage requirement and the total voltage rating of the devices or the components used in the system. Simulation and experimental results are presented to confirm the capability of the proposed MLI. [ABSTRACT FROM AUTHOR]

Published

2017

100. Analysis and Design of Closed-Loop Control of Electrolytic Capacitor-Less Six-Pulse DC Link Three-Phase Inverter.

Author

Ghoshal, Anirban, Pan, Xuewei, and Rathore, Akshay K

Subjects

*ELECTRIC inverters, *ELECTRIC power, *ELECTRIC vehicles, *HYBRID electric vehicles, *ELECTROLYTIC capacitors, *DIRECT currents

Abstract

Three-phase inverters in uninterrupted power supply, electric vehicles, and hybrid electric vehicles use an intermediate dc-link electrolytic capacitor, which has reliability issues and is one prominent cause of inverter failure and limited life. The large volume of an electrolytic capacitor increases the size and cost of the system. Recent research on electrolytic capacitorless inverters using six-pulse modulation technique along with high-frequency power conversion has attempted to address this issue. However, closed-loop operation and control has some issues due to capacitorless dc-link. In this paper, closed-loop operation, design, and implementation of an electrolytic capacitorless inverter is presented. A proof-of-concept 1-kW hardware prototype has been built and tested in a laboratory under different loading conditions. In total, 98% rated efficiency of the inverter is obtained with total harmonic distortion within 2%. Transient results during start-up and load change are smooth, demonstrating safe operation of the inverter. [ABSTRACT FROM AUTHOR]

Published

2017