Showing total 293 results

1. A Current Limiting Strategy With Parallel Virtual Impedance for Three-Phase Three-Leg Inverter Under Asymmetrical Short-Circuit Fault to Improve the Controllable Capability of Fault Currents.

Author

Lin, Xinchun, Liang, Zhigang, Zheng, Yun, Lin, Yibin, and Kang, Yong

Subjects

*FAULT currents, *PULSE width modulation transformers, *SHORT-circuit currents, *IMPEDANCE control, *FILTER paper, *VOLTAGE control, *ELECTRIC potential

Abstract

Voltage-controlled three-phase three-leg inverters are widely applied in various occasions. The inverters are generally switched to the current-controlled mode to limit the fault currents when short-circuit faults happen. Under symmetrical fault, the inverter can be controlled as a symmetrical, three-phase current source. However, the voltage limiting will happen under asymmetrical fault. As a result, the fault phase currents will be distorted and cannot be completely controlled. Considering that the voltage limiting is mainly caused by large load impedance of healthy phase under asymmetrical fault, the voltage limiting is avoided by paralleling the virtual impedance with the output filter capacitor in this paper. As a result, the current limiting loop is not broken and the fault phase currents can be effectively controlled. The implementation of virtual impedance in control system and the influence of virtual impedance on the stability of system are also analyzed in detail in this paper. The theoretical results are validated by experiments. [ABSTRACT FROM AUTHOR]

Published

2019

2. Cascaded Predictive Flux Control for a 3-L Active NPC Fed IM Drives Without Weighting Factor.

Author

Xiao, Dan, Akter, Md. Parvez, Alam, Kazi, Dutta, Rukmi, Mekhilef, Saad, and Rahman, Muhammed Fazlur

Subjects

*COST functions, *ALGORITHMS, *STATORS, *PREDICTION models, *VOLTAGE control

Abstract

Conventional model predictive control (MPC) for three-level active neutral point clamped converter (ANPC) utilizes weighting factors to achieve the optimal control of multiple control objectives in a single cost function. However, the selection of these weighting factors has an impact on the performance of the controlled objectives significantly. Tuning of weighting factors is usually tedious and lacks theoretical background. Moreover, the predictive and evaluation process for multiple objectives optimization have to be carried out by enumerating all admissible switching states within one loop. To simplify the complexity of this process and eliminate the effect of weighting factors, this paper proposes a cascaded predictive control scheme for a 3L-ANPC inverter fed induction machine (IM) drive. With the proposed approach, three separate cost functions for three control objectives, stator flux vector, neutral point voltage and device loss distribution are evaluated in a cascaded way, so that the optimization of these control objectives is performed independently. A 3L-ANPC inverter driven IM drive is studied in this paper to verify the effectiveness of the proposed algorithm. Experimental results in different operating conditions confirm that the proposed method achieves satisfactory steady-state and transient performances comparable to the conventional predictive control approach. The weighting factors used in the conventional method are eliminated and the computational effort is reduced by 68% compared to the conventional method without any sacrifice in the drive performance. [ABSTRACT FROM AUTHOR]

Published

2021

3. Dual-Hysteresis Band Control of Nine-Switch Inverter to Control Two Induction Motors.

Author

Gulbudak, Ozan and Gokdag, Mustafa

Subjects

*GATE array circuits, *IDEAL sources (Electric circuits), *VOLTAGE-frequency converters, *ELECTRIC current rectifiers, *INDEPENDENT sets, *TORQUE control, *VOLTAGE control, *INDUCTION motors

Abstract

This paper presents a dual-hysteresis band control method for multi-drive systems based on a nine-switch inverter. The drive system contains two independent three-phase induction motors fed by a nine-switch inverter. Independent control of torque, speed, and stator current of two load stages is achieved. The proposed strategy offers a reliable control operation of both induction machines under individual load profiles. Instead of using independent sets of three-phase voltage source converters, the nine-switch inverter is used to drive separate machines. Thus, the volume and size of the power stage are noticeably reduced due to the use of fewer semiconductors. The theoretical concept and design steps of the proposed method are presented. The performance of the closed-loop independent motor control scheme is experimentally validated using a 3.2 kW lab-scaled nine-switch inverter prototype and Altera Cyclone IV Field-programmable gate array. [ABSTRACT FROM AUTHOR]

Published

2022

4. Space Vector Modulation of Dual-Inverter System Focusing on Improvement of Multilevel Voltage Waveforms.

Author

Oto, Yoshiaki, Noguchi, Toshihiko, Sasaya, Takanari, Yamada, Takahiro, and Kazaoka, Ryoya

Subjects

*VECTOR spaces, *PULSE width modulation transformers, *HARMONIC distortion (Physics), *ELECTRIC potential, *VOLTAGE control, *PERMANENT magnet motors, *ELECTRIC capacity

Abstract

A space vector modulation (SVM) technique of a dual-inverter system for an open-end winding motor drive is described in this paper, where one inverter has a battery power source and the other has an only capacitor across the dc bus. The SVM must be achieved to operate the motor with field-oriented control and simultaneously to control the capacitor voltage at a constant value by using redundant switching states of the dual-inverter system. The control of the capacitor voltage is carried out by selecting a charging or a discharging mode in each redundant switching state, taking the instantaneous motor power factor into account. In addition, it is also required to reduce the error voltage pulses, which are generated in output multilevel voltage waveforms during the dead time. The compensation method of the existing dead-time scheme and the improved SVM sequence to reduce the error voltage vectors are proposed in this paper. The proposed methods are examined through several experimental tests and are confirmed to generate superior output voltage waveforms from the viewpoint of the measured total harmonic distortion and dv/dt. [ABSTRACT FROM AUTHOR]

Published

2019

5. A Seven-Level VSI With a Front-End Cascaded Three-Level Inverter and Flying-Capacitor-Fed H-Bridge.

Author

Abhilash, Tirupathi, Annamalai, Kirubakaran, and Tirumala, Somasekhar Veeramraju

Subjects

*RENEWABLE energy sources, *VOLTAGE control

Abstract

Multilevel inverters (MLIs) are playing a pivotal role in the power sector with potential applications, such as interfacing renewable energy sources with the grid and several industrial drive applications. MLIs with a smaller number of switching devices are more promising due to their compact size, reduced cost, and higher efficiency compared with their traditional counterparts. This paper, therefore, presents a new three-phase seven-level inverter. This topology is a combination of two cascade-connected two-level voltage-source inverters (VSIs) and H-bridge cells with flying capacitors (FCs). This paper presents the operating principle and the balancing technique for the dc-link capacitors and FCs. The generation of various output voltage levels and the limitation of the sinusoidal pulsewidth modulation control for FC voltage balancing is also presented. The number of components in the proposed circuit configuration and their voltage ratings are considerably lower compared with the recently proposed topologies. The behavior of the proposed circuit configuration is first assessed with simulation studies and is then tested with a laboratory prototype. The simulation and experimental results validate the effectiveness of the proposed topology and the voltage balancing technique. [ABSTRACT FROM AUTHOR]

Published

2019

6. Overload and Short-Circuit Protection Strategy for Voltage Source Inverter-Based UPS.

Author

Wei, Baoze, Marzabal, Albert, Perez, Jose, Pinyol, Ramon, Guerrero, Josep M., and Vasquez, Juan C.

Subjects

*IDEAL sources (Electric circuits), *OVERCURRENT protection, *SHORT circuits, *UNINTERRUPTIBLE power supply, *VOLTAGE control

Abstract

In this paper, an overload and short-circuit protection method is proposed for voltage source inverter-based uninterruptible power supply (UPS) system. In order to achieve high reliability and availability of the UPS, short circuit and overload protection scheme are necessary. When overload or short circuit happens, using the proposed control method, the amplitude of the output current can be limited to a constant value, which can be set by the customer to avoid the destruction of the power converter, and to obtain a faster recovery performance as well. The detailed principle of the proposed protection method is discussed in this paper. It mainly contains three parts in the control diagram for current limit, first is the anti-windup in the voltage and current controllers, then the feedforward of the capacitor voltage to the current control loop, the last is the fast reset of the resonant part of the current controller when overcurrent happens. The procedure of developing the control method is also presented in the paper. Experimental results on a commercial UPS system are presented to verify the effectiveness of the control method. [ABSTRACT FROM AUTHOR]

Published

2019

7. A Novel Seven-Level Active Neutral-Point-Clamped Converter With Reduced Active Switching Devices and DC-Link Voltage.

Author

Siwakoti, Yam P., Mahajan, Akshay, Rogers, Daniel J., and Blaabjerg, Frede

Subjects

*PULSE width modulation transformers, *REACTIVE power, *PASSIVE components, *ELECTRIC potential, *COST control, *SYSTEMS design

Abstract

This paper presents a novel seven-level inverter topology for medium-voltage high-power applications. It consists of eight active switches and two inner flying capacitor (FC) units forming a similar structure as in a conventional active neutral-point-clamped (ANPC) inverter. This unique arrangement reduces the number of active and passive components. A simple modulation technique reduces cost and complexity in the control system design without compromising reactive power capability. In addition, compared to major conventional seven-level inverter topologies, such as the neutral point clamped, FC, cascaded H-bridge, and ANPC topologies, the new topology reduces the dc-link voltage requirement by 50%. This recued dc-link voltage makes the new topology appealing for various industrial applications. Experimental results from a 2.2-kVA prototype are presented to support the theoretical analysis presented in this paper. The prototype demonstrates a conversion efficiency of around 97.2% ± 1% for a wide load range. [ABSTRACT FROM AUTHOR]

Published

2019

8. Control Strategy of DC-Link Voltage for Single-Phase Back-to-Back Cascaded H-Bridge Inverter for MV Drive With Interfacing Transformer Having Tertiary Winding.

Author

Yoo, Jeong-Mock, Jung, Hyun-Sam, and Sul, Seung-Ki

Subjects

*ELECTRIC potential, *VOLTAGE control, *CASCADE converters, *PULSE width modulation transformers, *MOTOR drives (Electric motors), *VOLTAGE-frequency converters, *REFERENCE values, *COMPUTER simulation

Abstract

This paper describes a dc-link voltage control method of a single-phase back-to-back cascaded H-bridge inverter (SBCI) for a medium-voltage motor drive system. The main advantage of the SBCI topology over the conventional regenerative cascaded H-bridge topology with a three-phase active front-end (AFE) is a simple system structure, which is composed of an input transformer, a power cell, a current sensor, etc. However, the challenging points of the SBCI are larger voltage ripple in the dc-link capacitor and imbalance of dc-link voltages of each phase. The asymmetric dc-link voltage of each power cells could cause unstable operation such as over-modulation due to the lack of the dc-link voltage of a particular phase and result in over-voltage or under-voltage faults. In this paper, the control strategy of the dc-link voltage for the SBCI that uses the negative-sequence voltage of the converter is described. The proposed control method is verified with a computer simulation whose target is a 6.6-kV–1.25-MW medium-voltage drive system. Also, through the experimental setup with the prototype SBCI whose power rating is 16.2 kVA, the dc-link voltage of each AFE has been controlled within a 0.5% error of its reference value at the full load. [ABSTRACT FROM AUTHOR]

Published

2019

9. Topology, Modeling and Control Scheme for a new Seven-Level Inverter With Reduced DC-Link Voltage.

Author

Khan, Shakil Ahamed, Barzegarkhoo, Reza, Guo, Youguang, Siwakoti, Yam, Khan, Md Noman Habib, Lu, Dylan Dah-Chuan, and Zhu, Jianguo

Subjects

*VOLTAGE, *TOPOLOGY, *ZERO voltage switching, *CAPACITOR switching, *ALGORITHMS, *REACTIVE power, *CAPACITORS, *PREDICTION models

Abstract

This paper presents a new single-source three-phase seven-level inverter with an inherent three-time voltage boosting capability for medium-voltage applications. The proposed topology is comprised of series connection of two switched-capacitor (SC) networks with an added half-bridge module per phase. Each of such integrated SC networks requires a single capacitor associated with three active power switches. The three-time voltage boosting feature of the proposed topology can reduce the dc-link voltage requirements by 50% in comparison to the traditional neutral point clamped (NPC), flying capacitors, active NPC (ANPC), hybrid clamped ANPC, and cascaded H-bridge topologies, and 75% to advanced ANPC topologies. It can also reduce the number of required switches and capacitors as well as their voltage stresses compared to those state-of-the-art topologies reported in the literature. By integrating “n” number of added SC networks in the proposed seven-level basic topology, the number of output voltage levels can be extended to 2n+3 per phase. A finite control set model predictive control algorithm is also derived to control the converter in both the active and reactive power exchanges modes without distorting the generated grid current quality. The capacitor voltage balancing is inherent in the proposed topology, and thus, there is no need for any additional voltage balancing circuit, which further reduces the control complexity. The performance of the proposed topology and its control algorithm are validated by several measurement results. [ABSTRACT FROM AUTHOR]

Published

2021

10. Analysis and Improvement of the Multiple Controller Interaction in LCC-HVDC for Mitigating Repetitive Commutation Failure.

Author

Hong, Lerong, Zhou, Xiaoping, Liu, Yifeng, Xia, Haitao, Yin, Hanhang, Chen, Yandong, Zhou, Leming, and Xu, Qianming

Subjects

*CURRENT fluctuations, *CURRENT limiters, *VOLTAGE control, *PROBABILITY theory

Abstract

In a line-commutated converter based high-voltage direct-current (LCC-HVDC) system, the inverter control system usually includes constant extinction angle (CEA) controller, constant current (CC) controller, current error controller (CEC), and voltage-dependent current order limiter (VDCOL). However, the interaction influence of multiple controllers may cause repetitive commutation failure (CF). For this purpose, this paper deeply investigates the mechanism and the influencing factors of repetitive CF caused by controller interaction. It is found that the lower limit value of CEA controller can affect the control switching process and thus the probability of repetitive CF. Besides, the minimum gamma measurement (MGM) unit prevents the system from acquiring the real extinction angle in time, which results in the DC current fluctuation during the recovery process. Moreover, the probability of control-induced repetitive CF is much higher when the HVDC inverter is connected to a weak AC system or the AC fault is not serious but not cleared in time. Based on the above analyses, an improved control method is proposed for recovery performance improvement, which is mainly realized by modifying the lower and upper limits of the CEA controller during recovery. Finally, the simulation and experimental results verify the theoretical analyses and the proposed control method. [ABSTRACT FROM AUTHOR]

Published

2021

11. Analysis of Output Voltage Ripple of AGPS for CFETR N-NBI Prototype.

Author

Zhang, Xueliang, Zhang, Ming, Ma, Shaoxiang, Wang, Shu, Pan, Yuan, and Yu, Kexun

Subjects

*ELECTRIC potential, *LEAKAGE inductance, *ELECTRIC power distribution grids, *COMPUTER simulation, *POWER resources

Abstract

The planned China fusion engineering test reactor (CFETR) needs one or more negative-ion-based neutral beam injectors (N-NBIs) with a beam energy of 500 or even 1000 keV. In order to prepare for CFETR, a prototype of CFETR N-NBI is being designed. The prototype needs an acceleration grid power supply (AGPS) rated at 200 kV/25 A with a maximum pulselength reaches to 3600 s. The AGPS adopted a single-stage inverter-type high-voltage power supply (HVPS). The output voltage ripple is an important specification of the AGPS, which can affect the efficiency and stability of N-NBI system by influencing the beam divergence. However, the conventional methods cannot be used to limit the output voltage ripple of the inverter-type HVPS used as AGPS of CFETR N-NBI prototype. This paper simplified the AGPS to an insulated three-phase three-level (TPTL) dc–dc converter connected with a dual dc link. The working process of the TPTL dc–dc converter with duty-cycle modulation has been analyzed, and two main continuous conduction modes are described. The influence of key parameters such as duty cycle of inverter, leakage inductance of transformer, and output current on output voltage ripple is analyzed. Based on the analysis results, a so-called combined control strategy was proposed to keep the output voltage ripple at a level. The proposed strategy is suitable for the cases where the object output voltage is below 175 kV. Some simulations were carried out by using MATLAB/Simulink. The results showed that the analysis in this paper is reliable and the proposed control strategy has a good performance. [ABSTRACT FROM AUTHOR]

Published

2019

12. A Fast-Dynamic Unipolar Switching Control Scheme for Single-Phase Inverters in DC Microgrids.

Author

Pokharel, Mandip, Hildebrandt, Nicolai, Ho, Carl Ngai Man, and He, Yuanbin

Subjects

*MICROGRIDS, *SINGLE-phase flow, *ELECTRIC inverters, *ELECTRIC potential, *ELECTRIC currents

Abstract

This paper presents the digital implementation of a boundary controller with unipolar switching characteristic for single-phase voltage source full-bridge inverters. This paper expands the application of a second-order switching surface-based control method to unipolar switching of single-phase voltage source inverters (VSIs) using a finite-state machine. The finite-state machine has been formulated considering four different states of the inverter; positive,zero1, negative, andzero2. The second-order boundary control governs the current state of the system and provides proper switching action to keep the system within the desired reference. The control law is implemented digitally in F28m35x digital control card. A full-bridge inverter topology is used to achieve the three-level voltage switching. Various simulations and experiments were performed in a 550 VA, 120 V, 60 Hz VSI with a digitally implemented controller to verify the theoretical predictions. A high-quality voltage output was obtained for various loading conditions. The transient performance of the controller was investigated using a reference and load changes. A comparison of the implementation was made with the existing classical controllers to verify the fast-dynamic response of the system. [ABSTRACT FROM AUTHOR]

Published

2019

13. A New PV Converter for a High-Leg Delta Transformer Using Cooperative Control of Boost Converters and Inverters.

Author

Yamaguchi, Daiki and Fujita, Hideaki

Subjects

*PHOTOVOLTAIC cells, *CONVERTERS (Electronics), *ELECTRIC inverters, *PHOTOVOLTAIC power generation, *ELECTRIC current converters

Abstract

This paper proposes a new high-efficiency photovoltaic (PV) converter for grid connection through a high-leg delta transformer. The converter is composed of a symmetrically connected boost converter and three half-bridge inverters. One of the three half-bridge inverters is connected to the boost converter, and the others are directly connected to the PV terminals. As a result, this circuit configuration enables to reduce the power losses in both boost converter and inverters. This paper also proposes a new cooperative control method between the symmetrically connected boost converter and inverter. The control method can reduce the average switching frequency to 75% of that in a conventional one, resulting in a great reduction in the switching power loss. Experimental results confirm that the proposed circuit configuration makes it possible to improve its European efficiency from 91.6% to 94.5%. Moreover, system performance is evaluated on the assumption of maximum power point tracking operation. [ABSTRACT FROM AUTHOR]

Published

2018

14. Load-Independent Class E/EF Inverters and Rectifiers for MHz-Switching Applications.

Author

Aldhaher, Samer, Yates, David C., and Mitcheson, Paul D.

Subjects

*SWITCHING circuits, *ZERO voltage switching, *ELECTRIC current rectifiers, *WIDE gap semiconductors, *WIRELESS power transmission

Abstract

This paper presents a unified framework for the modeling, analysis, and design of load-independent Class E and Class EF inverters and rectifiers. These circuits are able to maintain zero-voltage switching and, hence, high efficiency for a wide load range without requiring tuning or use of a feedback loop, and to simultaneously achieve a constant amplitude ac voltage or current in inversion and a constant dc output voltage or current in rectification. As switching frequencies are gradually stepping into the megahertz (MHz) region with the use of wide-bandgap (WBG) devices such as GaN and SiC, switching loss, implementing fast control loops, and current sensing become a challenge, which load-independent operation is able to address, thus allowing exploitation of the high-frequency capability of WBG devices. The traditional Class E and EF topologies are first presented, and the conditions for load-independent operation are derived mathematically; then, a thorough analytical characterization of the circuit performance is carried out in terms of voltage and current stresses and the power-output capability. From this, design contours and tables are presented to enable the rapid implementation of these converters given particular power and load requirements. Three different design examples are used to showcase the capability of these converters in typical MHz power conversion applications using the design equations and methods presented in this paper. The design examples are chosen toward enabling efficient and high-power-density MHz converters for wireless power transfer (WPT) applications and dc/dc conversion. Specifically, a 150-W 13.56-MHz Class EF inverter for WPT, a 150-W 10-MHz miniature Class E boost converter, and a lightweight wirelessly powered drone using a 20-W 13.56-MHz Class E synchronous rectifier have been designed and are presented here. [ABSTRACT FROM AUTHOR]

Published

2018

15. Analysis of a High-Power, Resonant DC–DC Converter for DC Wind Turbines.

Author

Dincan, Catalin, Kjaer, Philip, Chen, Yu-hsing, Munk-Nielsen, Stig, and Bak, Claus Leth

Subjects

*DIRECT current machinery, *CASCADE converters, *WIND turbines, *ELECTRIC transformers, *INSULATED gate bipolar transistors

Abstract

This paper is introducing a new method of operation for a series resonant converter, with intended application in megawatt high-voltage dc wind turbines. Compared to a frequency controlled series resonant converter operated in subresonant mode, the method (entitled pulse removal technique) allows the design of the medium frequency transformer for highest switching frequency, while being operated at lower frequency without saturation. The main focus of this paper is to identify and analyze the operating modes of the converter with pulse removal technique. With the use of variable frequency and variable phase displacement in subresonant mode, the new method of operation promises transformer size reduction and facilitates soft-switching transition of the insulated gate bipolar transistors (IGBTs) and line frequency diodes on rectifier side. Four modes of operation are identified, while equations for output power, voltage, and current stress are identified. Experimental results are concluded on a 1 kW, 250 V/500 V prototype. [ABSTRACT FROM AUTHOR]

Published

2018

16. Generation of High-Resolution 12-Sided Voltage Space Vector Structure Using Low-Voltage Stacked and Cascaded Basic Inverter Cells.

Author

Yadav, Apurv Kumar, Boby, Mathews, Pramanick, Sumit Kumar, Gopakumar, K., Umanand, Loganathan, and Franquelo, Leopoldo G.

Subjects

*VOLTAGE control, *LOW voltage systems, *ELECTRIC inverters, *CAPACITORS, *ELECTRONIC modulation

Abstract

This paper proposes generation of a 15-level (14 concentric) dodecagonal voltage space vector structure (DVSVS) for a star connected induction motor drive. The proposed multilevel DVSVS is obtained by cascading two inverters, namely a primary and secondary inverter. The primary inverter is a five-level (5L) structure formed by stacking two three-level flying capacitors with individual reduced dc sources and the secondary inverter is also a 5L structure formed by cascading two capacitor-fed cascaded H-bridges (CHB). The active power is supplied by the primary inverter, while the secondary inverter acts as switched capacitor harmonics filter, and capacitors in the secondary inverter are balanced naturally irrespective of load power factor for entire modulation index. The high-voltage dc supply fed primary inverter is operated in quasi-square wave mode, while the high frequency switching is applied to low voltage CHBs, thus, reducing the overall switching loss. The proposed scheme gives the advantages of both DVSVS and multilevel structure, thus, making it one of the solutions for battery or stacked dc-fed applications. The paper also presents the experimental results as well as comparison study with the existing topologies to support the advantages of proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2018

17. Instantaneous Phase Voltage Sensing in PWM Voltage-Source Inverters.

Author

Schubert, Michael and De Doncker, Rik W.

Subjects

*PULSE width modulation transformers, *ELECTROMECHANICAL devices, *ROTORS, *ELECTRIC potential, *POWER electronics, *ELECTRIC filters

Abstract

The output voltage of power electronic converters is a very important quantity for dynamic control of power electronic systems. In electrical drives without electromechanical position or speed sensor, the terminal reference voltage is used to obtain the rotor position. Dead-time effects and semiconductor voltage drop lead to distortion in the actual output voltage and degrade the control performance when the back electromotive force magnitude is low. Thus, for stable low-speed operation, output voltage sensing becomes necessary. Due to the switching nature of power electronic systems, this is not a trivial task, especially when instantaneous measurement of the terminal voltage is required. In this paper, an instantaneous switching-period average voltage sensing technique is proposed that utilizes a combined approach of oversampling and filtering. Based on the theoretical analysis of the sampling- and filter-induced measurement distortion, a general solution for an optimal filter design is derived. The additional sensing circuit is integrated into the low-side gate driver of the converter outputs. This paper includes details about the hardware implementation and extensive verification measurements. [ABSTRACT FROM AUTHOR]

Published

2018

18. Analysis and Prevention of Subsequent Commutation Failures Caused by Improper Inverter Control Interactions in HVDC Systems.

Author

Liu, Lei, Lin, Sheng, Liu, Jian, Sun, Peiyao, Liao, Kai, Li, Xiaopeng, and He, Zhengyou

Subjects

*HIGH voltages, *POWER (Social sciences), *VOLTAGE control, *PREVENTION

Abstract

This paper presents the essential reason for subsequent commutation failures (SCFs) in high voltage direct current (HVDC) systems, and accordingly proposes a novel adaptive extinction angle recovery (AEAR) control strategy to prevent SCFs. Firstly, based on the changes of the inverter control mode after the first CF, the interaction process of inverter control loops is divided into 3 stages and analyzed in detail. It is found that the control aim of DC current is ambiguous in stage 2, causing the output of current error control (CEC) to persist above zero. In stage 3, however, the CEC output drops rapidly, leading to an uncontrolled status of extinction angle and bringing the risk of SCFs. Furthermore, the precondition for the control mode switching is derived. On the basis of that, an AEAR control strategy is proposed. By adopting an adaptive extinction angle reference, the proposed scheme maintains the inverter at the constant extinction angle (CEA) mode after the first CF. Thus, the uncontrolled status of extinction angle can be avoided. The problem of SCFs due to improper inverter control interactions is also able to be fixed at the root. Simulation results show the validity of the analysis and the superiority of the proposed control strategy in preventing SCFs. [ABSTRACT FROM AUTHOR]

Published

2020

19. Novel Control Method for Multimodule PV Microinverter With Multiple Functions.

Author

Chiang, Hsuang-Chang, Lin, Faa-Jeng, and Chang, Jin-Kuan

Subjects

*PHOTOVOLTAIC power generation, *ELECTRIC switchgear, *VOLTAGE control, *DIRECT currents, *SIMULATION methods & models

Abstract

This paper presents a novel control method for multimodule photovoltaic microinverter (MI). The proposed MI employs a two-stage topology with active-clamped current-fed push–pull converter cascaded with a full-bridge inverter. This system can operate in grid-connected mode to feed power to the grid with a programmable power factor. This system can also operate in line-interactive mode, i.e., share load power without feeding power to the grid. In the event of grid power failure, the MI can operate in a standalone mode to supply uninterruptible power to the load. This paper presents a multiloop control scheme with power programmable capability for achieving the above multiple functions. In addition, the proposed control scheme embedded a multimodule parallel capability that multiple MI modules can be paralleled to enlarge the capacity with autonomous control in all operation modes. Finally, three 250-W MI modules are adopted to demonstrate the effectiveness of the proposed control method in simulations as well as experiments. [ABSTRACT FROM PUBLISHER]

Published

2018

20. Buck?Boost Dual-Leg-Integrated Step-Up Inverter With Low THD and Single Variable Control for Single-Phase High-Frequency AC Microgrids.

Author

Qin, Ling, Hu, Mao, Lu, Dylan Dah-Chuan, Feng, Zhiqiang, Wang, Yafang, and Kan, Jiarong

Subjects

*ELECTRIC inverters, *MATHEMATICAL variables, *MICROGRIDS, *HARMONIC distortion (Physics), *ELECTRONIC modulation, *STEADY state conduction

Abstract

To support the development of high-frequency ac microgrids in terms of compact design, high-voltage gain and low total harmonic distortion (THD), a buck–boost dual-leg-integrated step-up inverter is proposed in this paper. The inverter is formed by integrating a buck–boost converter into a conventional single-phase full-bridge inverter by sharing the upper switch and the body diode of the lower switch in both bridge-legs. Consequently, the component count is significantly reduced over the step-up inverter counterparts. In addition, to address the drawbacks of hybrid modulation methods adopted by existing dual-leg-integrated inverters, such as double-variable control, and high THD of output voltage/current at high input voltage and heavy load conditions, unipolar frequency doubling sinusoidal pulse width modulation scheme is adopted in this inverter. As a result, the modulation ratio M becomes the only control variable to regulate the output voltage/current and the control is simplified. The THD of the proposed inverter output can remain low throughout the entire input voltage range and load power range. This paper presents the topology derivation procedure, operation principle, and steady-state characteristics of the proposed inverter. To validate the effectiveness of theory, experimental results of a 400 W hardware prototype, where the output voltage frequency is at 500 Hz, are reported. [ABSTRACT FROM PUBLISHER]

Published

2018

21. Combination Analysis and Switching Method of a Cascaded H-Bridge Multilevel Inverter Based on Transformers With the Different Turns Ratio for Increasing the Voltage Level.

Author

Lee, June-Seok, Sim, Hyun-Woo, Kim, Juyong, and Lee, Kyo-Beum

Subjects

*ELECTRIC inverters, *SWITCHING theory, *VOLTAGE control, *ELECTRIC transformers, *ELECTRIC switchgear, *TOPOLOGY

Abstract

This paper analyzes the combination in a cascaded H-bridge multilevel inverter (CHBI) based on transformers with the different turn ratios for increasing the voltage level and proposes the switching method for achieving the output voltage distribution among H-bridge cells (HBCs). The transformers used in this paper are connected to the output of the respective HBCs, and the secondary sides of all the transformers are connected in series for generating the final output voltage. Only one of the transformers, in particular, has a different turn ratio for increasing the output voltage level. In this paper, the possible turn ratio of the special transformer with a different turn ratio is discussed in detail, and a switching method based on the level-shifted switching method for the topology used in this paper is proposed. To verify the effectiveness of the proposed method, a three-phase 21-level CHBI is experimentally tested. [ABSTRACT FROM PUBLISHER]

Published

2018

22. DTC of Three-Level NPC Inverter Fed Five-Phase Induction Motor Drive With Novel Neutral Point Voltage Balancing Scheme.

Author

Payami, Saifullah, Behera, Ranjan Kumar, and Iqbal, Atif

Subjects

*ELECTRIC inverters, *INDUCTION motors, *VOLTAGE control, *TORQUE control, *CAPACITORS, *SWITCHING circuits

Abstract

In this paper, direct torque control (DTC) of five-phase induction motor (FPIM) is implemented using three-level neutral point clamped (TL-NPC) inverter. One of the advantages of three-level inverter over two-level one for DTC operation is the low torque ripple. Also TL-NPC inverter through space vector modulation technique gives low $ dv/dt$ transition with better voltage waveform. By applying conventional lookup table for DTC, the TL-NPC inverter does not ensures lower $dv/dt$ transition. In this paper, a novel switching scheme for DTC of FPIM using TL-NPC inverter is proposed that ensures the low $ dv/dt$ transition and balancing of dc-link capacitor voltages of TL-NPC inverter. To form the lookup table for DTC operation, instead of using voltage vectors directly, virtual vectors (VVs) are utilized. Two switching states are used in one sample time to generate a VV in $\alpha \beta$ plane, which gives zero resultant voltage in $ xy$ plane. The switching strategy ensures low number of transitions to reduce the switching losses. The switching state redundancies are used in a novel way to balance the dc-link capacitor voltages without using any additional hardware. The proposed technique to balance the dc-link capacitor voltage gives lower switching frequency. The MATLAB/Simulink environment is used for the simulation and the results are validated through experiments. [ABSTRACT FROM AUTHOR]

Published

2018

23. Leakage Current Mitigation in Photovoltaic String Inverter Using Predictive Control With Fixed Average Switching Frequency.

Author

Rojas, Christian A., Aguirre, Matias, Kouro, Samir, Geyer, Tobias, and Gutierrez, Eduardo

Subjects

*PHOTOVOLTAIC power systems, *STRAY currents, *ELECTRIC inverters, *PREDICTIVE control systems, *VOLTAGE control

Abstract

This paper proposes and validates model predictive control as an alternative control strategy for H-bridgeneutral-point-clamped (H-NPC) converters for single-phase grid-tied string photovoltaic (PV) systems. The presented control scheme achieves good quality current waveforms with unity power factor, dc-link voltage control, and neutral-point voltage minimization. Furthermore, the predictive controller has been further enhanced by including an average device switching frequency restriction and a $dv/dt$ mitigation. The main contribution of this paper is the avoidance of the potential leakage current due to parasitic capacitance of the PV modules by using a predictive model based control technique instead of modulated schemes and eliminating high-frequency common-mode voltage components. Experimental results during steady state and dynamic operation are presented to illustrate the behavior of the H-NPC converter commanded by the proposed control scheme. [ABSTRACT FROM AUTHOR]

Published

2017

24. Study of Passivity-Based Decoupling Control of T-NPC PV Grid-Connected Inverter.

Author

Wang, Jiuhe, Mu, Xiaobin, and Li, Qing-Kui

Subjects

*PASSIVITY (Engineering), *PASSIVE components, *PHOTOVOLTAIC effect, *ELECTRIC power distribution grids, *SMART power grids

Abstract

For the purpose of improving the performances of T-type neutral point clamped (T-NPC) photovoltaic (PV) grid-connected inverter under large grid, a passivity-based decoupling control scheme is proposed in this paper. First, the Euler–Lagrange (EL) mathematical model of a T-NPC PV grid-connected inverter with an LC filter is built based on the power circuit and operating principles. Second, with this EL mathematical model and passivity of the inverter, the passivity-based controller is designed by the damping injecting method. Third, by adopting a proportional integral regulator to directly control direct current (dc) voltage, together with passivity-based indirect control, better performances of the dc voltage control can be further obtained. With the proposed passivity-based controller, the PV grid-connected inverter can achieve both dynamic current decoupling under the synchronous rotating dq coordinate and dc side voltage dynamic decoupling, which can improve the quality of the current connected into the power grid. The passivity-based PV grid-connected inverter is with strong robustness against parameters perturbations of resistors and attenuating the influence of delay in the inverter. Moreover, the passivity-based decoupling control scheme proposed in this paper for the T-NPC PV grid-connected inverter has a simple structure, and is easily debugged and realized in engineering. Experimental results under 10-kW prototype show that the proposed control scheme is effective. [ABSTRACT FROM PUBLISHER]

Published

2017

25. Secure High DER Penetration Power Distribution via Autonomously Coordinated Volt/VAR Control.

Author

Joseph, Anto, Smedley, Keyue, and Mehraeen, Shahab

Subjects

*VOLTAGE control, *VOLTAGE regulators, *CAPACITOR switching, *CAPACITOR banks, *POWER resources

Abstract

Traditionally voltage control in distribution power system (DPS) is performed through voltage regulating devices (VRDs) including on load tap changers (OLTCs), step voltage regulators (SVRs), and switched capacitor banks (SCBs). The recent IEEE 1547-2018 from March 2018 requires inverter fed distributed energy resources (DERs) to contribute reactive power to support the grid voltage. To accommodate VAR from DERs, well-organized control algorithm is required to use in this mode to avoid grid oscillations and unintended switching operations of VRDs. This paper presents two voltage control strategies (i) static voltage control considering voltage-reactive power mode (IEEE 1547-2018), (ii) dynamic and extensive voltage control with maximum utilization of DER capacity and system stability. Further, effective time-graded control is implemented between VRDs and DER units to reduce the simultaneous and negative operation. The proposed voltage control strategies are tested in a realistic 140-bus southern California distribution power system through extensive time-domain simulation studies. The results show that voltage quality in a distribution system is effectively achieved through the proposed voltage control strategies with a significantly reduction in the number of switching operations of VRDs. In addition, proposed voltage control strategies increase reliability and security of the DPS during unexpected failures. [ABSTRACT FROM AUTHOR]

Published

2020

26. An Effective Sliding Mode Control Design for a Grid-Connected PUC7 Multilevel Inverter.

Author

Makhamreh, Hamza, Trabelsi, Mohamed, Kukrer, Osman, and Abu-Rub, Haitham

Subjects

*SLIDING mode control, *ELECTRIC inverters, *COST functions, *PULSE width modulation transformers, *ONLINE algorithms, *SAMPLING errors

Abstract

This paper proposes an effective sliding mode controller (SMC) for a grid-connected 7-level packed U-cell (PUC7) inverter. The aim is to design a simple controller that deals effectively with the complex control problem of the PUC7 inverter (multiobjective control problem). The selection of the control actions is achieved according to the system state error at every sampling time, regardless of the previous values, which makes the control technique model-independent. The control algorithm evaluates online two cost functions (one for each state error), which are derived on the basis of sliding mode theory, and it selects the optimal control input in order to satisfy the reaching conditions of the two cost functions. Compared with the existing solutions, the proposed SMC technique ensures lower average switching frequency by tuning the hysteresis bandwidth of the capacitor-voltage error. The fast implementation, needless of gains tuning, and simple design procedure are the main features of the proposed algorithm. Simulation and experimental results are presented to prove the effectiveness of the proposed technique in controlling the PUC7 inverter with high dynamic performance and robustness against disturbances and parameters mismatch. [ABSTRACT FROM AUTHOR]

Published

2020

27. Simultaneous Common-Mode Voltage Reduction and Neutral-Point Voltage Balance Scheme for the Quasi-Z-Source Three-Level T-Type Inverter.

Author

Qin, Changwei, Zhang, Chenghui, Xing, Xiangyang, Li, Xiaoyan, Chen, Alian, and Zhang, Guangxian

Subjects

*ELECTRIC potential, *PLANT shoots, *VOLTAGE control

Abstract

The conventional three-level inverter only has voltage buck capability. The quasi-Z-source three-level T-type inverter (QZS 3LT $^2$ I) has been proposed to realize voltage buck–boost operation. In this paper, we further propose a novel modulation scheme for the QZS 3LT $^2$ I to realize voltage boosting, reduce the common-mode voltage (CMV), and control the neutral-point voltage balance simultaneously. The proposed scheme adopts a large vector, a medium vector, a small vector with low CMV magnitude, a zero vector, and a shoot-through vector to generate the output voltage. According to sector number and neutral-point voltage difference, a p-type or n-type small vector with low CMV magnitude is properly selected to balance the neutral-point voltage. Shoot-through states are inserted within zero vector to boost the dc input voltage without affecting the ac output voltage. Dwell times of basic vectors are calculated through the revised volt–second balance equation. Furthermore, a coordinate control strategy between neutral-point voltage balance and voltage boosting is proposed. Doing so, the CMV magnitude can be restricted within one-sixth of dc-link voltage and neutral-point voltage imbalance can be effectively mitigated. The effectiveness of the proposed scheme is verified by simulations and experiments. [ABSTRACT FROM AUTHOR]

Published

2020

28. Internal Model Based Smooth Transition of a Three-Phase Inverter Between Islanded and Grid-Connected Modes.

Author

Yazdani, Sara, Ferdowsi, Mehdi, and Shamsi, Pourya

Subjects

*HIGHER order transitions, *DISTRIBUTED power generation, *PHASE-locked loops, *SMART structures, *ELECTRIC inverters, *ADAPTIVE control systems

Abstract

Recent technical advances in control, protection and interconnection of distributed power generation units imply that it is practically viable and economically profitable to keep them as backup generators in isolated operating modes. Therefore, along with the development of islanding detection techniques, seamless operation in transition between islanded and grid connected modes is required and more sophisticated control strategies are needed to recognize the existing working condition and adjust the performance to meet the strict standards of grid interconnection. This paper presents a new adaptive control structure, based on internal model control (IMC), which uses multiple models and an inherent islanding detection method through an optimized switching mechanism to tune the operation of a three-phase inverter under transitions between islanded and grid-tied conditions. By applying a power synchronization method, the system emulates the operation of a synchronous machine which is needless to rely on a phase-locked loop to synchronize during the transitions. Hardware co-simulation environment in Simulink/PLECS and Xilinx System Generator have been utilized to evaluate the transient behavior of the controller in discretized domain and verify its robustness during parameter variations and load switching conditions. Various switching rules have been applied and a comparison of their effect in transient response is demonstrated. The results, taken from several case studies, confirm the significant robustness of the proposed control methodology. [ABSTRACT FROM AUTHOR]

Published

2020

29. Modeling and Simulation of a Novel Active Three-Phase Multilevel Power Factor Correction Front End – The “Negev” Rectifier.

Author

Barbie, Eli, Rabinovici, Raul, and Kuperman, Alon

Subjects

*CORRECTION factors, *VOLTAGE control, *ELECTRIC current rectifiers, *HIGH voltages, *SIMULATION methods & models, *ELECTRIC potential

Abstract

This paper presents a modification of the Vienna rectifier (VR) to obtain more than three voltage levels at the DC line connection, while preserving the unity power factor at the AC grid side. The proposed unidirectional multilevel there-phase rectifier, called the “Negev rectifier”, has a reduced device count and utilizes a unique novel Time Division Multiplexed based control scheme, which makes the challenging N-level VR expansion possible. The Negev rectifier can serve as a grid interface for supplying dc voltage to multilevel inverters with 4 up to 7 voltage levels, eliminating the burden of inverter-side voltage balancing control. The Negev hardware can be constructed by two complementary topologies, making it suitable for either high current or high voltage applications. [ABSTRACT FROM AUTHOR]

Published

2020

30. A Nine-Level Inverter for Low-Voltage Applications.

Author

Zhang, Yunlei, Wang, Qunjing, Hu, Cungang, Shen, Weixiang, Holmes, Donald Grahame, and Yu, Xinghuo

Subjects

*PULSE width modulation transformers, *CAPACITORS, *VOLTAGE control

Abstract

A novel nine-level inverter topology for low-voltage applications is proposed in this paper. Each phase of the inverter is composed of a T-type three‐level cell and an active neutral point clamp three‐level cell. The operation principles and current conduction paths are analyzed in detail and phase-disposition sinusoidal pulsewidth modulation is used to balance voltages of flying capacitors and neutral point. The mathematical relationship between the capacitance and the desired ripple in the inverter output is established to select the intermediate capacitance value. Compared with other nine-level inverters suitable for low-voltage applications, the proposed inverter has advantages in a number of gate drivers, a number of dc sources, and efficiency. Simulation and experimental results under different settings of modulation index, power factor, output frequency, and load are presented to verify the effectiveness and performances of the proposed inverter. [ABSTRACT FROM AUTHOR]

Published

2020

31. LQR Control of Single-Phase Grid-Tied PUC5 Inverter With LCL Filter.

Author

Arab, Naima, Vahedi, Hani, and Al-Haddad, Kamal

Subjects

*PULSE width modulation transformers, *HARMONIC distortion (Physics), *RENEWABLE energy sources, *VOLTAGE control, *FILTERS & filtration

Abstract

This paper presents the current control design procedure of a single-phase grid-tied five-level packed U-cell inverter (PUC5) with an LCL output filter. The PUC5 inverter is used as an interface of renewable energy sources, such as solar applications. The LCL filter is calculated according to the grid-tied operation and converter ratings. An optimal controller, based on a linear quadratic regulator with integral action, is designed to inject a sinusoidal current with low harmonic distortion at unity power factor. For that design, the PUC5 inverter is modelled in the D–Q frame. The sensorless voltage control is incorporated into the switching technique to balance the PUC5 capacitor voltage and generate a five-level waveform at the output. Experimental tests are performed on a laboratory benchmark to confirm the theoretical design. The results prove the efficiency and accuracy of the adopted control strategy in a steady state and under transients of grid current, grid inductance, ac and dc voltage amplitudes. [ABSTRACT FROM AUTHOR]

Published

2020

32. An Enhanced Model Predictive Control Using Virtual Space Vectors for Grid-Connected Three-Level Neutral-Point Clamped Inverters.

Author

Alhosaini, Waleed, Wu, Yuheng, and Zhao, Yue

Subjects

*VECTOR spaces, *ELECTRIC inverters, *PREDICTION models, *RENEWABLE energy sources, *IDEAL sources (Electric circuits), *COST functions

Abstract

Reliability of power systems can be improved by the use of voltage source inverters (VSIs) with fast dynamic control, which can handle uncertainties induced by renewable energy resources and nonlinear loads. To ensure fast-dynamic response and simplified controller design, various model predictive control (MPC) methods are investigated in this paper. In the conventional MPC design for three-level VSIs, the cost function requires an additional term to ensure the balance of the neutral-point voltage (NP-V), which however can considerably impact the main goal of the MPC. To address this issue, an enhanced MPC using virtual space vectors is proposed, which allows the use of a significantly reduced weighting factor for the term in the cost function for NP-V balancing, while retaining fast-dynamic response. Additionally, the proposed MPC leads to reduced harmonic distortion in the VSI output voltage and current. Both simulation and controller hardware-in-the-loop studies are performed to demonstrate the effectiveness of the proposed enhanced MPC in an operating microgrid under both steady-state and fast-transient conditions. [ABSTRACT FROM AUTHOR]

Published

2019

33. Topology and Modulation Scheme for Three-Phase Three-Level Modified Z-Source Neutral-Point-Clamped Inverter.

Author

Ho, Anh-Vu and Chun, Tae-Won

Subjects

*TOPOLOGY, *VOLTAGE control

Abstract

This paper presents the topology and modulation technique of a three-phase three-level modified Z-source neutral-point-clamped (MZS-NPC) inverter, which combines a modified Z-source impedance network and a three-phase three-level NPC inverter. The boost factor of the proposed MZS-NPC inverter is twice as high as the three existing representative topologies combing an impedance network with a three-level NPC inverter. A modulation scheme for the proposed topology, based on a maximum boost control method, is designed to achieve the maximum voltage gain with simple implementation and to balance the dc-link neutral-point voltage. A closed-loop control of the ac load voltage in the fuel-cell or photovoltaic applications based on the proposed inverter is realized, in order to supply a desired voltage to the critical load in islanding mode of a microgrid. The boosting ability and operation validity of the proposed topology and modulation technique are demonstrated with simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

34. A Hybrid 7-Level Inverter Using Low-Voltage Devices and Operation With Single DC-Link.

Author

Yadav, Apurv Kumar, Gopakumar, K., R, Krishna Raj, Umanand, Loganathan, Bhattacharya, Subhashish, and Jarzyna, Wojciech

Subjects

*PULSE width modulation transformers, *INDUCTION motors, *INDUCTION machinery, *SEMICONDUCTOR devices, *VOLTAGE control, *POWER resources, *CAPACITORS

Abstract

This paper proposes a new 7-level inverter topology for induction motor drives. It is a hybrid topology formed by cascading a 5-level active neutral-point-clamped inverter with a 3-level T-type converter. It is obtained using low-voltage semiconductor devices with voltage blocking capability of Vdc/3 and Vdc/6. The topology uses three floating capacitors per phase, which are balanced within a pulsewidth modulation (PWM) switching duration using switching-state redundancies for each pole-voltage level. Topology forms two stacks at the front-end, which requires individual symmetrical dc source. The analysis of switching loss and conduction loss is performed and compared with some of the existing 7-level multi-level inverters reported in various literatures to show the advantages of the proposed topology. Furthermore, the single dc source operation with two stacked capacitors and closed-loop control of neutral-point voltage using symmetrical six-phase induction motor is proposed. The voltage-control algorithms for floating capacitors and dc-link stacked capacitors are proposed, which are independent of load power factor and modulation index. Open-loop V/f and closed-loop rotor field oriented control are performed, and various results at steady and transient states are presented to validate the aforementioned claims. [ABSTRACT FROM AUTHOR]

Published

2019

35. Variable Switching Frequency ON–OFF Control for Class E DC–DC Converter.

Author

Li, Ying, Ruan, Xinbo, Zhang, Li, Dai, Jiandong, and Jin, Qian

Subjects

*AC DC transformers, *CASCADE converters, *HIGH voltages, *CLINICAL pathology, *VOLTAGE control, *ELECTRIC potential

Abstract

The efficiency improvement of the on–off controlled Class E dc–dc converter operated at 20 MHz switching frequency is investigated in this paper. It is found that with the on–off control, the input power of the converter during the on mode increases with the increase of the input voltage, and it can be reduced by increasing the switching frequency. With this discovery, a variable switching frequency (VSF) on–off control is proposed, which slightly increases the switching frequency when the input voltage increases, maintaining the input power during the on mode slightly higher than the rated output power over the entire input voltage range, and thus highly improving the efficiency of Class E dc–dc converter at high input voltage. A prototype of 9-V–18-V input, 10-W Class E dc–dc converter has been fabricated and tested in the lab. The experimental results show that the proposed VSF on–off control improves the conversion efficiency of the Class E dc–dc converter by 4%–10% compared to the constant switching frequency on–off control. [ABSTRACT FROM AUTHOR]

Published

2019

36. A Novel Discontinuous PWM Strategy to Control Neutral Point Voltage for Neutral Point Clamped Three-Level Inverter With Improved PWM Sequence.

Author

Jiang, Weidong, Li, Laibao, Wang, Jinping, Ma, Mingna, Zhai, Fei, and Li, Jinsong

Subjects

*PULSE width modulation transformers, *VOLTAGE control, *ELECTRIC potential, *PULSE width modulation inverters, *PULSE width modulation, *LOSS control

Abstract

In order to reduce switching loss of neutral point clamped three-level inverter (NPC TLI), generally discontinuous pulsewidth modulation (DPWM) is used. But it can result in dc offset and ac ripple on neutral point (NP) voltage. So a novel pulse sequence DPWM (NPSDPWM) is proposed to reduce switching loss and control NP voltage simultaneously in this paper. NP voltage is controlled by choosing proper clamping modes. To avoid unexpected switching action during changing clamping mode, an improved pulse sequence is also presented. The switching loss and NP voltage ripple of NPSDPWM, traditional and proposed DPWM in previous literature are compared, respectively. The experimental results show that NPSDPWM has well NP voltage control ability and the switching losses are reduced effectively. [ABSTRACT FROM AUTHOR]

Published

2019

37. Improved Space Vector Modulation Technique for Neutral-Point Voltage Oscillation and Common-Mode Voltage Reduction in Three-Level Inverter.

Author

Xing, Xiangyang, Li, Xiaoyan, Gao, Feng, Qin, Changwei, and Zhang, Chenghui

Subjects

*VECTOR spaces, *ELECTRIC inverters, *TORQUE control, *PULSE width modulation transformers, *ELECTRIC potential, *VOLTAGE control, *OSCILLATIONS, *ELECTRICAL conductivity transitions

Abstract

Three-level inverter has an outstanding performance and is more advantageous in the switching vector selection than two-level inverter. In particular, the neutral-point voltage unbalance and common-mode voltage (CMV) reduction of three-level inverter should be carefully regulated for the appropriate operation, both of which, however, are mutually coupled resulting that the conventional space vector modulation (SVM) scheme cannot deal with them properly. To overcome this limitation, this paper proposes an improved space vector modulation (ISVM) technique to reduce the CMV and neutral-point voltage imbalance simultaneously. The generating mechanism of neutral-point voltage oscillation is derived. Based on the analysis, the proposed ISVM method adopts four voltage vectors (large, medium, small, and zero vectors) with adjusted dwell times to eliminate the ac unbalance of the neutral-point voltage. Considering the occurrence of neutral-point voltage disturbances, the dc neutral-point unbalance voltage is controlled by selecting the P-type or N-type small vector and adjusting the dwell times of small vectors for neutral-point voltage recovery. In addition, a novel switching sequence arrangement method with the minimal number of switches transition in one switching cycles and between switching cycles is proposed to reduce the total switching loss. Theoretical analysis and verification results show that the proposed ISVM scheme can reduce the magnitude of CMV to half of value using the conventional SVM, and an accurate control of ac and dc unbalanced neutral-point voltage can be obtained. [ABSTRACT FROM AUTHOR]

Published

2019

38. Multiphase-Interleaved High Step-Up DC/DC Resonant Converter for Wide Load Range.

Author

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

Subjects

*ZERO voltage switching, *DC-to-DC converters, *ELECTRIC network topology, *CASCADE converters, *RESONANT inverters, *MATHEMATICAL analysis, *VOLTAGE-frequency converters, *VOLTAGE control

Abstract

A multiphase-interleaved non-isolated high step-up dc/dc resonant converter for high-current applications with wide load range is proposed in this paper. The converter consists of an inverter stage with multiple resonant inverters in parallel interleaving operation that is cascaded to a common diode–capacitor rectifier stage. The topology of the inverter stage is a variation of class E inverter, which is designed for voltage boosting and of which the voltage gain is insensitive to load change. The rectifier stage comprises multiple pairs (correlated to the number of inverters in parallel) of diodes in parallel and a small output capacitor, which makes it simple to implement and of low cost. Together, the voltage gain variance of the converter can be confined within a small value and zero voltage switching operation can be maintained over a wide load range. A detailed mathematical analysis of the proposed converter is conducted for systematizing its design. A prototype of the proposed converter with an input voltage of 23.6 V, a rated output voltage of 190 V, and a rated output power of 80 W at 486 kHz is constructed for verification. A frequency controller is implemented to achieve fine regulation of the output voltage. [ABSTRACT FROM AUTHOR]

Published

2019

39. Extending the Linear Modulation Range to the Full Base Speed Using a Single DC-Link Multilevel Inverter With Capacitor-Fed H-Bridges for IM Drives.

Author

S, Arun Rahul, Pramanick, Sumit, Kaarthik, R. Sudharshan, Gopakumar, K., and Blaabjerg, Frede

Subjects

*ELECTRIC inverters, *CAPACITORS, *CIRCUIT elements, *ELECTRIC capacity, *ELECTRICAL harmonics

Abstract

In this paper, a new space vector pulse width modulation method to extend the linear modulation range of a cascaded five level inverter topology with a single dc supply is presented. Using this method, the inverter can be controlled linearly and the peak phase fundamental output voltage of the inverter can be increased from 0.577 to 0.637 V\text{dc} without increasing the dc bus voltage and without exceeding the induction motor voltage rating. This new technique makes use of cascaded inverter pole voltage redundancy and property of the space vector structure for its operation. Using this, the induction motor drive can be operated till the full speed range (0–50 Hz) with the elimination of lower order harmonics in the phase voltage and phase current. The five-level topology presented in this paper is realized by cascading a two-level inverter and two full bridge modules with floating capacitors. The inverter topology and its operation for extending the modulation range is analyzed extensively. Simulation and experimental results for both steady-state and dynamic operating conditions are presented in this paper. [ABSTRACT FROM AUTHOR]

Published

2017

40. Improvement of Power Quality Using a Robust Hybrid Series Active Power Filter.

Author

Swain, Sushree Diptimayee, Ray, Pravat Kumar, and Mohanty, Kanungo Barada

Subjects

*FORCE & energy, *ELECTRIC power filters, *ELECTRIC potential, *ROBUST control, *COMPUTER simulation

Abstract

The degradation in power quality causes adverse economical impact on the utilities and customers. Harmonics in current and voltage are one of the most commonly known power quality issues and are solved by the use of a hybrid series active power filter (HSAPF). In this paper, a new controller design using sliding-mode controller-2 is proposed to make the HSAPF more robust and stable. An accurate averaged model of a three-phase HSAPF is also derived in this paper. The design concept of the robust HSAPF has been verified through simulation and experimental studies, and the results obtained are discussed. [ABSTRACT FROM AUTHOR]

Published

2017

41. Extended Linear Modulation Operation of a Common-Mode-Voltage-Eliminated Cascaded Multilevel Inverter With a Single DC Supply.

Author

S, Arun Rahul, Pramanick, Sumit, Boby, Mathews, Gopakumar, K., and Franquelo, Leopoldo G.

Subjects

*ELECTRONIC modulation, *CAPACITORS, *INDUCTION motors, *MOTOR drives (Electric motors), *HARMONIC distortion (Physics), *ELECTRIC inverters

Abstract

Zero-common-mode-voltage (CMV) operation of multilevel inverters results in reduced dc-bus utilization and reduced linear modulation range. In this paper, a method to increase the linear modulation range for zero-CMV operation without increasing the dc-bus voltage using a cascaded multilevel inverter with a single dc supply is presented. Using this method, the peak fundamental output voltage can be increased from 0.499 to 0.637  \textV\text{dc} with zero CMV inside the linear modulation range. Also, various pulse width modulation (PWM) switching sequences are analyzed in this paper, and the PWM sequence that gives minimum current ripple is used for the zero-CMV operation of the inverter. The inverter topology with single dc supply is realized by cascading a two-level inverter with two floating-capacitor-fed full-bridge modules. Simulation and experimental results for steady-state and dynamic operating conditions are presented to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2016

42. Seven-Level Unipolar/Bipolar Pulsed Power Generator.

Author

Rocha, L. Lamy, Silva, J. Fernando, and Redondo, L. M.

Subjects

*FIELD-effect transistors, *PULSED power systems, *DIODES, *CAPACITORS, *RESISTIVE force

Abstract

This paper shows how to use modular Marx multilevel converter diode ( \textM^3 CD) modules to apply unipolar or bipolar high-voltage pulses for pulsed power applications. The \textM^3 CD cells allow the assembly of a multilevel converter without needing complex algorithms and parameter measurement to balance the capacitor voltages. This paper also explains how to supply all the modular cells in order to ensure galvanic isolation between control circuits and power circuits. The experimental results for a generator with seven levels, and unipolar and bipolar pulses into resistive, inductive, and capacitive loads are presented. [ABSTRACT FROM AUTHOR]

Published

2016

43. A Novel Ten-Switch Topology for Unified Power Quality Conditioner.

Author

Rauf, Abdul Mannan, Sant, Amit Vilas, Khadkikar, Vinod, and Zeineldin, H. H.

Subjects

*ELECTRIC power systems, *THREE-phase alternating currents, *TOPOLOGY, *ELECTRIC switchgear, *PERFORMANCE evaluation

Abstract

This paper proposes a new topological configuration for a unified power quality conditioner (UPQC). Generally, the power structure of the three-phase three-wire UPQC consists of two back-to-back connected six-switch inverters. For this configuration, out of 12 switches, six of the series inverter switches will be underutilized most of the time. To improve the semiconductor utilization and consequently to reduce the total switch count, this paper proposes a new reduced switch topology for the UPQC. The proposed topology is realized using only ten switches and retains all the performance merits of the 12-switch UPQC while minimizing its underutilization without increasing the switch VA rating. The paper provides a detailed analytical study and evaluation by comparing the proposed topology with the twelve- and nine-switch-based UPQC system configurations. The feasibility of the proposed topology is validated through experimental investigation. [ABSTRACT FROM AUTHOR]

Published

2016

44. Model Predictive Control for a Dual-Active Bridge Inverter With a Floating Bridge.

Author

Chowdhury, Shajjad, Wheeler, Patrick W., Gerada, Chris, and Patel, Chintan

Subjects

*PREDICTIVE control systems, *ELECTRIC inverters, *ELECTRIC transformers, *DIRECT currents, *ELECTRIC potential

Abstract

This paper presents a model predictive control technique applied to a dual-active bridge inverter where one of the bridges is floating. The proposed floating bridge topology eliminates the need for isolation transformer in a dual inverter system and therefore reduces the size, weight, and losses in the system. To achieve multilevel output voltage waveforms, the floating inverter dc-link capacitor is charged to the half of the main dc-link voltage. A finite-set model predictive control technique is used to control the load current of the converter as well as the floating capacitor voltage. Model predictive control does not require any switching sequence design or complex switching time calculations as used for space vector modulation; thus, the technique has some advantages in this application. A detailed analysis of the converter as well as the predictive control strategy is given in this paper. Simulation and experimental results to validate the approach are also presented. [ABSTRACT FROM PUBLISHER]

Published

2016

45. A Multilevel Converter With a Floating Bridge for Open-End Winding Motor Drive Applications.

Author

Chowdhury, Shajjad, Wheeler, Patrick W., Patel, Chintan, and Gerada, Chris

Subjects

*CONVERTERS (Electronics), *MOTOR drives (Electric motors), *INDUCTION motor efficiency, *ELECTRIC inverters, *CAPACITORS

Abstract

This paper presents a three-phase open-end winding induction motor drive. The drive consists of a three-phase induction machine with open stator phase windings and dual-bridge inverter supplied from a single dc voltage source. To achieve multilevel output voltage waveforms, a floating capacitor bank is used for the second of the dual bridges. The capacitor voltage is regulated using redundant switching states at half of the main dc-link voltage. This particular voltage ratio (2:1) is used to create a multilevel output voltage waveform with three levels. A modified modulation scheme is used to improve the waveform quality of this dual inverter. This paper also compares the losses in the dual-inverter system in contrast with a single-sided three-level neutral point clamped converter. Finally, detailed simulation and experimental results are presented for the motor drive operating as an open-loop v /f controlled motor drive and as a closed-loop field-oriented motor controller. [ABSTRACT FROM PUBLISHER]

Published

2016

46. An Improved Adjustable Modulation Strategy for Three-Level NPC Inverters Considering Dynamic Loading Applications.

Author

Mukherjee, Sarbani, Giri, Santu Kumar, and Banerjee, Subrata

Subjects

*PULSE width modulation transformers, *DYNAMIC loads, *INDUCTION machinery, *PULSE width modulation

Abstract

Three-level neutral-point-clamped (NPC) inverters are being widely adopted in low-voltage low-power applications. For an intended application, the modulation strategy and the operating conditions are the two key factors that highly influence the major performance indices of the NPC inverter, such as efficiency, harmonic distortion, and voltage oscillations at neutral point (NP). Considering dynamic loading applications where the operating point varies significantly, this paper proposes an improved adjustable pulsewidth modulation (PWM) strategy for a three-level NPC inverter that can alter its modulation pattern to meet desired performance objectives for the full operation range. It has been shown that by varying two control parameters namely discontinuity control parameter and bias control parameter, the proposed modulation strategy changes its pattern between the most efficient generalized discontinuous PWM to NP oscillations-free partial dipolar PWM strategy. Additionally, to obtain a tradeoff between the performance parameters—efficiency, NP oscillations, and waveform quality—The proposed strategy has the ability to settle at the intermediate modulation patterns by transforming into a hybrid modulation signal. Furthermore, considering NP voltage unbalance mitigation as major technical challenge in adjustable modulation strategy, a voltage unbalance compensator that exhibits satisfactory balancing performance for the entire variations of modulation patterns and operating conditions has also been presented. The performance of the proposed modulation strategy in conjunction with voltage unbalance compensator has been evaluated in simulation by widely varying the speed and load of induction motor, and verified in experimentation. [ABSTRACT FROM AUTHOR]

Published

2019

47. A Constant Switching Frequency Model Predictive Control Without Weighting Factors for T-Type Single-Phase Three-Level Inverters.

Author

Yang, Yong, Wen, Huiqing, Fan, Mingdi, Xie, Menxi, Chen, Rong, and Wang, Yiwang

Subjects

*ELECTRIC inverters, *RENEWABLE energy sources, *CASCADE converters, *ELECTRIC power distribution grids, *VOLTAGE control

Abstract

This paper presents a novel model predictive control (MPC) for the T-type single-phase three-level inverters. The cumbersome procedure in tuning of weighting factors is eliminated so that the implementation of the proposed MPC becomes easy. The constant switching frequency is achieved during the control implementation in order to facilitate the filter design. In order to optimize the distribution of the output current harmonics, multiple voltage vectors are employed in each control cycle with their application times setting inversely proportion to the respective cost function. The redundant small voltage vectors are utilized to balance the neutral point voltage of the inverter by directly regulating the upper and lower dc-link capacitors voltages. Finally, the proposed MPC algorithm is experimentally evaluated and compared with other two unfixed switching frequency MPC algorithms in terms of the steady state, transient performance, and parameter sensitivity. [ABSTRACT FROM AUTHOR]

Published

2019

48. A Boost-Type Nine-Level Switched Capacitor Inverter.

Author

Nakagawa, Yuya and Koizumi, Hirotaka

Subjects

*CAPACITOR switching, *PULSE width modulation transformers, *ELECTRIC capacity, *ON-chip charge pumps, *CAPACITORS, *VOLTAGE control, *MULTI-carrier modulation

Abstract

A new boost-type multilevel inverter using switched capacitor structure is proposed. The main feature of the proposed inverter is boosting and multilevel output with small number of components. Due to the passive voltage balancing of each capacitor maintains a constant voltage without additional control. In this paper, the operation principle, the modulation method, the voltage/current stresses on switches and the determination of capacitances, the simulation results with MATLAB/Simulink R2015a, the experimental results, and the 2-kW simulation are shown. The simulation and the experiments were conducted under resistive load and inductive load conditions. In addition, the load variation was conducted in the experiment. Under both resistive load and inductive load conditions, the obtained waveforms by simulation and experiment agreed well with the theory. In the load variation experiment, the obtained waveforms were not distorted and the capacitor voltages maintained constant. [ABSTRACT FROM AUTHOR]

Published

2019

49. Feedback Linearization Control in Photovoltaic Module Integrated Converters.

Author

Callegaro, Leonardo, Ciobotaru, Mihai, Pagano, Daniel J., and Fletcher, John E.

Subjects

*MAXIMUM power point trackers, *DC-to-DC converters, *CASCADE converters, *ELECTRONIC feedback, *VOLTAGE-frequency converters, *VOLTAGE control, *ELECTRIC potential

Abstract

The strive to increase the energy yield of photovoltaic (PV) power systems has made PV module integrated dc–dc converters (dc-MICs) a reality of modern PV plants. These converters regulate their input voltage, and their dynamic behavior is heavily influenced by the non-linear characteristic of the PV module. The regulation of the PV module voltage and average inductor current by means of a linear cascaded controller is a popular control technique, simplifying the converter dynamics, and providing inherent current limiting; however, it is prone to instability depending on the interaction between the PV source and the interfacing converter, as well as the value of the controller parameters. These factors present a clear challenge for control design; moreover, the converter transient response undesirably depends on the PV module operating point. In order to solve these issues, while maintaining regulation of PV module voltage and average inductor current, this paper proposes to adopt a non-linear controller designed with the feedback linearization control (FLC) technique. The control laws are derived and implemented in a non-inverting buck–boost dc module integrated converter, as this is a favorite topology for the PV interfacing application. A digitally controlled converter prototype is built and used to obtain experimental results, where the FLC technique is compared with a linear cascaded control technique. The results confirm the superior performance of the presented FLC technique, which is robust and able to regulate the converter input voltage with fast and consistent dynamics, regardless of the PV module or load operating conditions. [ABSTRACT FROM AUTHOR]

Published

2019

50. A Novel Bidirectional T-Type Multilevel Inverter for Electric Vehicle Applications.

Author

Sheir, Ahmed, Youssef, Mohamed Z., and Orabi, Mohamed

Subjects

*ELECTRIC inverters, *ELECTROLYTIC capacitors, *POWER capacitors, *ROTARY converters, *CAPACITOR switching

Abstract

This paper introduces a new configuration of bidirectional multilevel converter in electric vehicle (EV) applications. It has multilevel dc–dc converter with a dc link capacitor voltage balance feature. The multilevel dc–dc converter operates in a bidirectional manner, which is a fundamental requirement in EVs. Compared to the conventional configurations, the proposed one only implements two extra power switches and a capacitor to balance the voltage of the T-type multilevel inverter (MLI) capacitor over a complete drive cycle or at fault conditions. Therefore, no extra isolated sensor, control loops, and/or special switching pattern are required. Moreover, the proposed configuration due to the high-frequency cycle-by-cycle voltage balance between ${C_N}$ and ${C_P}$ , the bulky electrolytic capacitors used in T-type MLI, are replaced with more reliable longer life film capacitors. This will result in a size and weight reduction of the converter by 20%. This allows more real estate for the EV battery in the chassis’ space envelope to increase its capacity. The proposed configuration is tested and validated using a matlab/Simulink simulation model. A laboratory prototype of 1 kW is built to provide the proof of concept results as well. [ABSTRACT FROM AUTHOR]

Published

2019