Showing total 6,270 results

151. A Comprehensive Review Toward the State-of-the-Art in Failure and Lifetime Predictions of Power Electronic Devices.

Author

Hanif, Abu, Yu, Yuechuan, DeVoto, Douglas, and Khan, Faisal

Subjects

*ELECTRONIC equipment, *POWER electronics, *ELECTRONICS, *FAILURE analysis

Abstract

This paper discusses various types of failure mechanisms, precursor parameters, and accelerated aging-based procedures to estimate the remaining life of power electronic devices. Special attention has been given to summarize the different techniques typically used for measuring the junction temperature, because it plays a vital role during accelerated aging and condition monitoring. We reviewed more than 250 papers, and the references list 139 of them in order to explain and address the advantages and disadvantages of various techniques toward the reliability prognosis. Thus, this paper can be considered as an expedient reference to conduct future research on lifetime prediction of existing power electronic devices. [ABSTRACT FROM AUTHOR]

Published

2019

152. Advanced Digital Controller for Improving Input Current Quality of Integrated Active Virtual Ground-Bridgeless PFC.

Author

Siu, Ken King-Man, He, Yuanbin, Ho, Carl Ngai Man, Chung, Henry Shu-Hung, and Li, River Tin-Ho

Subjects

*DC-to-DC converters, *ARCHITECTURE, *ELECTROMAGNETIC interference, *QUALITY

Abstract

This paper presents a new digital control scheme for active virtual ground-bridgeless PFC (AVG-BPFC), which is able to obtain an optimized solution between the system efficiency and electromagnetic interference performance in the PFC stage. However, a resonant characteristic is generated from the input LCL filter structure of the converter. In addition, there is a phase difference between two inductor currents which also leads the controller design in the AVG-BPFC to become challenging, especially on the system stability and current quality. Thus, a triple loop control's architecture together with an integrated state machine is proposed as the control methodology of the AVG-BPFC. Under the simple control structure in the digital platform, a stable system is achieved together with a precise grid current tracking function. Such control scheme was implemented digitally on a 1.5 kW prototype. In this paper, theoretical models of the whole system were analyzed and the system performance was successfully verified in both steady state and transient state conditions. The experimental results show a good agreement with the theoretical knowledge. [ABSTRACT FROM AUTHOR]

Published

2019

153. Analysis and Comparison of Notch Filter and Capacitor Voltage Feedforward Active Damping Techniques for LCL Grid-Connected Converters.

Author

Rodriguez-Diaz, Enrique, Freijedo, Francisco D., Vasquez, Juan C., and Guerrero, Josep M.

Subjects

*NOTCH filters, *CAPACITOR switching, *CAPACITORS, *ELECTRIC potential

Abstract

The use of LCL filters is a well-accepted solution to attenuate the harmonics created by the pulsewidth modulation. However, inherently LCL filters have a resonance region where the unwanted harmonics are amplified, which can compromise stability. Several techniques have been developed in order to tackle this issue. At first the use of passive damping, by intentionally increasing the resistance of the LCL filter components, is a simple, robust, and straightforward solution; however, it decreases the overall efficiency of the system, and hence in general is unwanted. Alternatively, active damping strategies, where the resonance damping is provided by the current controller, are of major interest. This paper analyzes the robustness of the closed-loop dynamics when different active damping techniques are implemented. The analyzed active damping techniques, which have been selected because of their readiness and simplicity, are: 1) filtered capacitor voltage feedforward and 2) second-order filters in cascade with the main current controller. The impedance/admittance stability formulation is used to model the system, which has been proven to be very convenient for the assessment of robustness. Experimental tests are provided in order to show the accuracy of the analysis and verify the findings. This paper proves that filtered capacitor voltage feedforward is a more robust and reliable solution than implementations based on cascade notch filters. [ABSTRACT FROM AUTHOR]

Published

2019

154. Bidirectional Series Resonant DC/AC Converter for Energy Storage Systems.

Author

Ibanez, Federico Martin

Subjects

*GRID energy storage, *CASCADE converters, *ENERGY storage, *ROTARY converters

Abstract

This paper presents a novel bidirectional series resonant converter for energy storage systems (ESS). Conversion between a dc energy storage device and an ac grid has grown in importance because of the renewable energy generators and ESS used in microgrids, which usually use batteries or supercapacitors as storage devices in order to provide different services and improve the quality and reliability of the grid. This novel converter avoids the need to have two converting stages: one for converting the energy from the storage device to a regulated dc value, and the other for converting the regulated dc to the ac output. Conversion occurs via a modified dc/dc dual-bridge series resonant converter. The output bridge of the converter is attached to the input bridge through a resonant branch and a high frequency (HF) transformer, and it is also attached to the ac link through an output filter. Therefore, two ac power signals are mixed in the output bridge: a HF signal, which maintains the dc link capacitor voltage, and a low frequency power signal, which transfers energy to the grid. This paper details the different working modes of the converter and presents a 3000 W prototype that validates the design. [ABSTRACT FROM AUTHOR]

Published

2019

155. Improving the Overall Efficiency of Automotive Inverters Using a Multilevel Converter Composed of Low Voltage Si mosfets.

Author

Chang, Fengqi, Ilina, Olga, Lienkamp, Markus, and Voss, Leon

Subjects

*AUTOMOBILE power trains, *LOW voltage systems

Abstract

In order to improve the driving range and reduce the cost of battery electric vehicles through a higher efficiency, this paper proposes to adopt multilevel converters using low-voltage Si mosfets in the electric powertrains. A multilevel Si mosfet inverter, a conventional insulated-gate bipolar transistor (IGBT) inverter, and a SiC mosfet inverter are modeled and compared using a reference vehicle over various driving cycles. The costs of the three solutions are also compared. It is shown that the multilevel Si mosfet inverter has a rather high efficiency and realizes the lowest cost among the three solutions even when the worst case of cost is considered. Sensitivity analysis also shows that the multilevel Si mosfet inverter is suitable for a wide range of vehicle concepts in addition to the reference vehicle. Moreover, the multilevel topology also features lower electromagnetic interference and provides modularity. Therefore, Si mosfet-based multilevel inverters are proved in this paper to be an appropriate option to improve the efficiency and reduce the cost of electric powertrains. [ABSTRACT FROM AUTHOR]

Published

2019

156. Complex-Based Controller for a Three-Phase Inverter With an LCL Filter Connected to Unbalanced Grids.

Author

Doria-Cerezo, Arnau, Serra, Federico Martin, and Bodson, Marc

Subjects

*ELECTRIC inverters, *FILTERS & filtration

Abstract

A new controller for a grid-connected inverter with an LCL filter is proposed in this paper. The system is described by its complex representation, and the controller is designed using the complex root locus method. The complex representation allows a considerable reduction in the order of the system, simplifying the design task and making it possible to use advanced techniques, such as the complex root locus. The new complex controller adds an extra degree of freedom that makes it possible to move the poles of the systems and to improve the stability and speed of response compared with the conventional controls. This paper includes a detailed discussion of the effect of the gains of the controller on the root locus. The proposal is validated with simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

157. A Unified Controller for Utility-Interactive Uninterruptible Power Converters for Grid Connected and Autonomous Operations.

Author

S, Shan and Umanand, Loganathan

Subjects

*ELECTRIC network topology, *ELECTRIC power distribution grids

Abstract

This paper proposes a unified control based utility-interactive uninterruptible power converter (UIUPC). The proposed control enables the UIUPC to inherently transfer from a $ p-q$ control strategy in grid-connected mode to a voltage–frequency control strategy in autonomous mode and vice-versa. This happens seamlessly with the same control topology. The need to switch between two separate control architectures is thus eliminated. Critical islanding detection and synchronizing mechanisms are also not needed in the proposed control method. The unified controller proposed in this paper is derived from the concept of controlling the perturbations in the magnitude and speed of the point of common coupling (PCC) space vector. The PCC space vector is compared with a reference space vector applied in the direction of the PCC space vector on an instantaneous basis to extract the perturbations. The reference system of the proposed control is linked to the dynamics of the PCC space vector. This offers the ability of parallel operation of similar unified control UIUPC. Thus, in addition to the above said advantages, the proposed control also puts forth an alternative to paralleling approaches like conventional droop and master–slave configurations. The effectiveness of the proposed control is validated by simulation and experimentation. [ABSTRACT FROM AUTHOR]

Published

2019

158. Optimized 12-Pulse Rectifier With Generalized Delta Connection Autotransformer and Isolated SEPIC Converters for Sinusoidal Input Line Current Imposition.

Author

de Oliveira Costa Neto, Antonio, Soares, Ana Lucia, de Lima, Gustavo Brito, Rodrigues, Danillo Borges, Coelho, Ernane Antonio Alves, and Freitas, Luiz Carlos Gomes

Subjects

*HYBRID electric vehicles

Abstract

This paper discusses an alternative to reduce harmonic current distortion in a 12-pulse rectifier. The circuit is based on a generalized autotransformer connection with low power-to-core that feeds two isolated SEPIC converters. Compared to other passive devices operating as conventional 12-pulse rectifiers, besides a tight dc bus, the use of static converters can, by means of an active current imposition, provide very low harmonic distortion of current. This paper presents a theoretical analysis which is corroborated by computational and experimental results. The results show that the performance of the proposed converter is similar to the performance provided by three-phase unity power factor PWM rectifiers, however, only two active switches are deployed. [ABSTRACT FROM AUTHOR]

Published

2019

159. GaN VHF Converters With Integrated Air-Core Transformers.

Author

Zhang, Zhiliang, Xu, Ke, Xu, Zhi-Wei, Xu, Jiahua, Ren, Xiaoyong, and Chen, Qianhong

Subjects

*MODULATION-doped field-effect transistors, *SILICON nitride, *POWER density

Abstract

This paper proposes an air-core transformer integration method, which mounts the transformer straight into the multilayer printed circuit board (PCB), and maintains a proper distance between the inner transformer and other components on the top layer. The integration method reduces the PCB area significantly, ensuring higher power density. The design of the complete structure is accomplished with finite element analysis (FEA) to ensure that the unconstrained transformer magnetic field does not affect other components. It is applied to three resonant flyback converters operating at 20 MHz with Si mosfets, 30 MHz, and 50 MHz with enhancement-mode gallium nitride (eGaN) high-electron mobility transistors, respectively. The 30-MHz eGaN prototype achieves the full load efficiency of 80.1% (an increase of 1.1% compared with the 20-MHz Si prototype) and power density of 32 W/in3 at 5-V input and 5 V/ 2 W output. The 50-MHz eGaN prototype achieves the power density of 39.4 W/in3, which is 41% higher than the 20-MHz Si prototype. With the similar efficiency, the overall height of the converters in this paper is less than half of the commercial products, very suitable for low thickness and profile applications. [ABSTRACT FROM AUTHOR]

Published

2019

160. Hybrid Modulation Scheme for Switching Loss Reduction in a Modular Multilevel High-Voltage Direct Current Converter.

Author

Kim, Seok-Min, Jeong, Min-Gyo, Kim, Juyong, and Lee, Kyo-Beum

Subjects

*CASCADE converters, *HIGH-voltage direct current converters

Abstract

A modular multilevel converter (MMC) is regarded as a promising topology in high-voltage direct current systems. However, the MMC consists of numerous submodules (SMs) and switching devices, which lead to a considerable switching loss, and increased cost and size of the heat sink. To mitigate these issues, this paper presents a novel modulation method composed of fundamental frequency modulation (FFM) and multicarrier-based sinusoidal pulsewidth modulation schemes. The main purpose of this modulation method is the reduction of switching loss while maintaining good harmonic performance. However, the FFM scheme leads to the unbalanced capacitor voltage of each SM in the MMC. Accordingly, this paper additionally proposes the rotation method and selective voltage balancing control for SMs to ensure effective performance of the method. Simulation and experimental results verify the effectiveness and performance of the proposed modulation scheme through switching loss and spectral analyses. [ABSTRACT FROM AUTHOR]

Published

2019

161. Stability Analysis for the Grid-Connected Single-Phase Asymmetrical Cascaded Multilevel Inverter With SRF-PI Current Control Under Weak Grid Conditions.

Author

Han, Yang, Chen, Hao, Li, Zipeng, Yang, Ping, Xu, Lin, and Guerrero, Josep M.

Subjects

*ELECTRON tube grids, *ELECTRIC power system stability, *SINGLE-phase alternating currents, *ELECTRIC inverters, *ELECTRIC circuits

Abstract

This paper analyzes the influence of phase-locked loop (PLL) on the stability of LCL-type single-phase grid-connected asymmetrical cascaded H-bridge multilevel inverter (ACHMI) with synchronous reference frame proportional-integral (SRF-PI) grid current control under weak grid scenarios. The ACHMI system is composed of power stage circuit and control system, where the control system contains the dual-loop current control strategy established in the hybrid reference frame, the SRF-PLL, and the hybrid modulation method employed to synthesize the multilevel output voltage. The small-signal model of the whole ACHMI system is first established by using a simple step-by-step derivation method, and then, the small-signal analysis method is adopted to linearize the ACHMI, which is then utilized to derive the impedance model of the ACHMI system. Furthermore, an improved impedance stability criterion is derived, which is then employed to analyze the system stability. By using this criterion, the stability of the ACHMI can be evaluated with the variation of the bandwidth of PLL, the output power factor angle of the ACHMI, and the amplitude of the grid current reference signal under weak grid conditions. In this paper, a systematic design procedure for the optimal selection of the PI controller of the PLL is presented, which guarantees the steady-state performance and dynamic response of the ACHMI system. With this design method, the dual-loop current control and PLL can be taken into account simultaneously when analyzing the stability margin of the ACHMI. Finally, the simulation and experimental results from a down-scaled grid-connected ACHMI prototype system are provided to confirm the validity of theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

162. A Novel AC Power Loss Model for Ferrite Power Inductors.

Author

Stoyka, Kateryna, Capua, Giulia Di, and Femia, Nicola

Subjects

*ENERGY dissipation, *FERRITES, *POWER inductors, *SWITCHING power supplies, *ELECTRIC potential

Abstract

Recent studies have proved that sustainable saturation operation of Ferrite Power Inductors (FPIs) allows reducing the inductor size and increasing the power density in Switch-Mode Power Supply (SMPS) applications. This paper discusses a new behavioral model for reliable prediction of ac power loss in FPIs, including the effects of saturation. The new model has been identified by means of the Genetic Programming (GP) algorithm combined with a Multi-Objective Optimization (MOO) technique, starting from large sets of power loss experimental measurements. The proposed ac power loss model uses as input variables the voltage and switching frequency imposed to the inductor by the SMPS operation, while the dc inductor current is used as a parameter expressing the impact of saturation. Such quantities can be easily determined for whatever converter topology and in real-world switching operation, thus confirming the readiness and the easiness-to-use of the proposed behavioral model. The results of experimental tests presented in this paper prove the reliability of the power loss predictions, also by correctly accounting for the impact of inductors saturation. [ABSTRACT FROM AUTHOR]

Published

2019

163. An Improved Fundamental Harmonic Approximation to Describe Filter Inductor Influence on Steady-State Performance of Parallel-Type Resonant Converter.

Author

Chen, Yiming, Xu, Jianping, Sha, Jin, Lin, Leiming, and Cao, Jing

Subjects

*HARMONIC analysis (Mathematics), *ELECTRIC filters, *ELECTRIC inductors, *CONVERTERS (Electronics), *STEADY-state responses

Abstract

The influence of a filter inductor on the steady-state performance of a parallel-type resonant converter is elaborated and analyzed in this paper. By steady-state operation analysis, it is shown that the ripple current of the filter inductor results in an inaccurate prediction of fundamental harmonic approximation (FHA), and such problem would become serious when the filter inductance is small. In order to portray such feature, an improved fundamental harmonic approximation (IFHA) is proposed. Unlike an FHA equivalent circuit, an equivalent inductor is added to the ac resistance parallelly in an IFHA equivalent circuit. Due to that, the equivalent inductor branch takes account of the ripple current of the filter inductor, and the IFHA is expected to own higher accuracy and can be used in a parameter design procedure. In this paper, the equivalent inductor expressions of full-bridge rectifier and current-doubler rectifier are derived as examples. In order to verify the theoretical analysis, a 500 W LCC resonant converter is built as a prototype. The close-loop experiment results show that small filter inductance would lead to the failure of output voltage regulation and hard-switching operation of power switches. And open-loop experiment results show the IFHA gives more accurate predictions than those of FHA. [ABSTRACT FROM AUTHOR]

Published

2019

164. A Single-Stage Soft-Switching High-Frequency AC-Link PV Inverter: Design, Analysis, and Evaluation of Si-Based and SiC-Based Prototypes.

Author

Khodabandeh, Masih, Afshari, Ehsan, and Amirabadi, Mahshid

Subjects

*ELECTRIC inverter design & construction, *SILICON carbide, *ELECTRIC power transmission, *ENERGY conversion, *POWER density

Abstract

This paper proposes a high-power-density and reliable inverter topology, which transfers the maximum power of a PV array to the load in one power conversion stage. The single-stage power conversion, along with the soft-switching capability of the proposed three-phase PV inverter promises high efficiency at all operating points. Instead of a capacitive dc link that decouples the dc–dc converter and the voltage source inverter in traditional two-stage PV inverters, a high-frequency capacitive ac link is employed in the proposed inverter, which enables exploiting a very small film capacitor, rather than a bulky electrolytic capacitor, for transferring power. Eliminating electrolytic capacitors prolongs the lifetime of this inverter. Considering the long lifetime of PV modules, this feature is of high importance in PV applications. The high-frequency ac link also allows using high-frequency transformers for providing galvanic isolation. Therefore, this inverter is expected to have a very high power density. This paper presents principles of the operation and control, design, and analysis of this inverter, and verifies the performance of the inverter through two prototypes: a 2-kW Si-based prototype and a 2-kW SiC-based prototype operating at different switching frequencies. [ABSTRACT FROM AUTHOR]

Published

2019

165. Three-Phase Custom Power Active Transformer for Power Flow Control Applications.

Author

Elsaharty, M. A., Rocabert, J., Candela, Jose Ignacio, and Rodriguez, Pedro

Subjects

*THREE-phase alternating currents, *ELECTRIC transformers, *ELECTRIC controllers, *ELECTRIC current rectifiers, *CONSTRAINTS (Physics)

Abstract

This paper presents the three-phase custom power active transformer (CPAT), characterized by the integration of power electronics in a transformer to facilitate grid services. Such integration enables step-up/step-down transformation between primary and secondary as well as shunt and series compensation services to the power system through a single transformer. The CPAT can empower the grid with flexible ac transmission system and power quality services such as power flow control, reactive power compensation, active filter, and voltage regulation through a single monolithic transformer. In this paper, designs of the three-phase CPAT are realized and analyzed based on their equivalent magnetic circuit as well as their structure requirements and constraints. Simulation analysis of the three-phase CPAT clarifies its capability to actively regulate power flow between the primary and secondary windings as well as achieve grid harmonic current compensation. Moreover, through real-time simulations and an experimental prototype, the merits and performance of the three-phase CPAT were further validated. [ABSTRACT FROM AUTHOR]

Published

2019

166. On Exploiting Active Redundancy of a Modular Multilevel Converter to Balance Reliability and Operational Flexibility.

Author

Kang, Jaesik, Kim, Heejin, Jung, Hong-Ju, Lee, Dong-Su, Kim, Chan-Ki, Mantooth, H. Alan, and Hur, Kyeon

Subjects

*CONVERTERS (Electronics), *CURRENT balances (Electric meters), *FAULT tolerance (Engineering), *ELECTRIC potential, *SIMULATION methods & models

Abstract

This paper presents a practical strategy for utilizing the submodule (SM) redundancy of a modular multilevel converter (MMC) for its fault tolerance. This strategy provides a systematic framework for balancing the tradeoff between two conventional methods for using the active redundancy and, thus, achieves operational flexibility. One of the existing methods improves SM reliability owing to less voltage stress on the SM components by employing all of the SMs to form the ac or dc voltages (voltage-sharing mode). The other avoids transients by keeping the average SM voltage constant at the cost of slightly increased stress on the SM components (fixed-level mode), which, however, can be controlled to provide the grid-adaptive operation by reserving the energy of the SMs not in service. We, thus, develop a new redundancy management scheme by integrating these two methods and exploiting their technical benefits to meet the PQ requirements and MMC control performance. This research provides a theoretical basis and a technical guide to determining the number of SMs, which can further increase the voltage steps as per the MMC and grid conditions. This paper also connects the remaining PQ capability of the MMC at a particular operating point with the SM redundancy concept by defining a potential redundancy, especially useful when the physical redundancy is exhausted. The theoretical findings and efficacy of the proposed strategy are validated through PSCAD/EMTDC time-domain simulations followed by experiments using a nine-level single-phase MMC system. [ABSTRACT FROM AUTHOR]

Published

2019

167. Investigation on Extending the DC Bus Utilization of a Single-Source Five-Level Inverter With Single Capacitor-Fed H-Bridge Per Phase.

Author

Davis, Teenu Techela and Dey, Anubrata

Subjects

*DIRECT currents, *ELECTRIC inverters, *CAPACITORS, *TOPOLOGY, *ELECTRIC switchgear

Abstract

Enhancement of dc bus voltage utilization for a five-level inverter with single dc source and capacitor-fed H-bridge (CHB) units is investigated in this paper. A carrier-based modulation technique is used for boosting the dc bus utilization, which is established by providing detailed mathematical analysis. The five-level inverter used here is realized by cascading a CHB unit to each phase of a three-level neutral point clamped inverter. The increase in dc bus voltage utilization owes to the pole voltage redundancies offered by CHB units. The floating capacitors of H-bridge units are balanced within a quarter fundamental cycle using the switching state redundancies of pole voltage levels. The aforementioned modulation technique allows the inverter to enhance the dc bus utilization from 0.577 $\text{V}_{\text{dc}}$ to 0.63 $\text{V}_{\text{dc}}$ under unity power factor. This enhancement is obtained in the linear modulation range without increasing the dc bus voltage, and thus, the inverter can operate without the presence of low-order harmonics in its phase voltages. The strength of this paper lies in its detailed mathematical analysis for finding out the limiting modulation index and power factor condition in the light of floating capacitor voltage balancing issue. Simulation as well as experimental verification of the modulation scheme is carried out on an induction motor drive under various operating conditions. It is shown that this carrier-based modulation technique is suitable for any single source inverter topology with one CHB unit per phase. [ABSTRACT FROM AUTHOR]

Published

2019

168. A New Single DC Source Six-Level Flying Capacitor Based Converter With Wide Operating Range.

Author

Ebrahimi, Javad and Karshenas, Hamidreza

Subjects

*DIRECT currents, *CONVERTERS (Electronics), *CAPACITORS, *ELECTRIC power factor, *HYBRID systems

Abstract

This paper presents a new six-level flying capacitor based (FC-based) multilevel converter with one dc source and the capability of operating in all power factors and modulation indexes. Multilevel converters with one dc voltage source are attractive in many applications as they do not need rather expensive and bulky multiwinding input transformer connection at the dc side. On the other hand, not all classic multilevel converters with one dc source can produce any desirable number of output voltage levels at all power factors and/or modulation indexes. In this paper, a hybrid structure is proposed in which six voltage levels can be realized at the ac terminals. The modulation technique and the control strategy for the FC voltage balancing are presented. To show the advantages of the proposed converter, different performance criteria, such as switch count and rating, the size of capacitors, switching frequency, and power losses, are compared with other existing six-level topologies. The results indicate that the proposed structure is superior to other six-level converters from different standpoints. Simulation results are used to further evaluate the performance of the proposed converter. A laboratory-type experimental setup is used to validate the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2019

169. Cancelation of Torque Ripples in PMSM via a Novel Minimal Parameter Harmonic Flux Estimator.

Author

Qamar, Nezar Yehya Abou and Hatziadoniu, Constantine J.

Subjects

*TORQUE control, *PARAMETER estimation, *HARMONIC analysis (Mathematics), *STATORS, *ELECTRIC controllers

Abstract

This paper presents a novel approach for treating the harmonic torque in permanent magnet motors at selected harmonic orders. The method is based on the online estimation of the motor harmonic flux. For this purpose, a novel minimal parameter harmonic flux estimator (MPHFE) is developed. The MPHFE is formulated such that the inductance, resistance, and stator current and its derivative are not necessary for the estimation of the harmonic flux. This was achieved by forcing the harmonic current to zero through the combined action of a field-oriented controller (FOC) and a feedforward controller. Subsequently, the harmonic flux can be obtained directly from the estimated harmonic back EMF without the involvement of other motor parameters. Finally, the estimated flux is used in conjunction with a comprehensive model of the motor harmonic torque to determine the stator current compensation for eliminating the torque harmonic. Experimental results presented from a permanent magnet motor confirm the theoretical claims in this paper as well as demonstrate the effectiveness of the proposed method to reduce the magnitude of the harmonic torque significantly. [ABSTRACT FROM AUTHOR]

Published

2019

170. A Modified DC Power Electronic Transformer Based on Series Connection of Full-Bridge Converters.

Author

Zhang, Jiepin, Liu, Jianqiang, Yang, Jingxi, Zhao, Nan, Wang, Yang, and Zheng, Trillion Q.

Subjects

*DIRECT currents, *POWER electronics, *ELECTRONIC transformers, *CONVERTERS (Electronics), *ELECTRIC potential, *POWER semiconductors, *POWER density

Abstract

This paper proposes a novel dc power electronic transformer (DCPET) topology for locomotive, ac/dc hybrid grid, dc distribution grid, and other isolated medium-voltage and high-power applications. Compared with conventional PET topology, the proposed DCPET has fewer power semiconductor devices and high-frequency isolation transformers, which can improve the power density and reliability. Fault handling or redundancy design can be achieved to further improve the reliability when some dc–dc modules break down. Also, input voltage sharing control can be omitted to simplify the control system and improve the stability. Meanwhile, soft switching is guaranteed for all the switches, which is beneficial to increase switching frequency and improve power density. In this paper, the principle, evolution, and control of the proposed DCPET are respectively presented and studied in detail. Finally, a prototype of the proposed DCPET is built and the experimental results verify the validity and superiority of the proposed topology. [ABSTRACT FROM AUTHOR]

Published

2019

171. Optimized Modulation and Dynamic Control of a Three-Phase Dual Active Bridge Converter With Variable Duty Cycles.

Author

Huang, Jun, Li, Zhuoqiang, Shi, Ling, Wang, Yue, and Zhu, Jinda

Subjects

*CASCADE converters, *THREE-phase alternating currents, *ENERGY conversion, *ELECTRIC transformers, *ELECTRIC transients

Abstract

The three-phase dual active bridge (3p-DAB) converter is a promising topology for high power dc–dc conversion due to advantages of bidirectional power flow, inherent soft-switching capability, and reduced filter volume. This paper presents comprehensive analysis of the duty cycle control (DCC) for optimizing the performance of the 3p-DAB. Based on DCC, an optimized modulation strategy is proposed to minimize the conduction losses of the 3p-DAB in the whole load range. The proposed modulation strategy extends the soft-switching range of the 3p-DAB with large voltage variations simultaneously. It is established through loss analysis that the proposed modulation strategy boosts the efficiency of the 3p-DAB, especially at low loads. When the duty cycles change fast as a result of the abruptly changed transmission power, the transformer currents can become unbalanced, leading to the magnetic bias and oscillations in dc currents. This paper further proposes a fast transient current control (FTCC) method for the 3p-DAB with variable duty cycles. The FTCC enables the converter to transfer from one steady state to another within about one-third switching period, hence balancing the transformer currents rapidly and avoiding oscillations in dc currents. Finally, experimental results verify the outstanding performance of the proposed modulation strategy and FTCC method. [ABSTRACT FROM AUTHOR]

Published

2019

172. LCLC Converter With Optimal Capacitor Utilization for Hold-Up Mode Operation.

Author

Chen, Yang, Wang, Hongliang, Hu, Zhiyuan, Liu, Yan-Fei, Liu, Xiaodong, Afsharian, Jahangir, and Yang, Zhihua

Subjects

*CASCADE converters, *HIGH voltages, *ELECTRIC inductors, *MAGNETIZATION, *SWITCHING circuits

Abstract

In data center and telecommunication power supplies, the front-end dc–dc stage is required to operate with a wide input voltage range to provide hold-up time when ac input fails. Conventional LLC converter serving as the dc–dc stage is not suitable for this requirement, as the normal operation efficiency (at 400 V input) will be penalized once the converter is designed to achieve high peak gain (wide input voltage range). This paper examined the operation of the LCLC converter and revealed that the LCLC converter could be essentially equivalent to a set of LLC converters with different magnetizing inductors that are automatically adjusted for different input voltages. In nominal 400 V input operation, the LCLC converter behaves like an LLC converter with large magnetizing inductor, thus the resonant current is small. In the hold-up period, when the input voltage reduces, the equivalent magnetizing inductor will reduce together with switching frequency reducing, thus the converter achieves high peak gain. In this paper, a new design methodology is also proposed to achieve optimal utilization of the two resonant capacitors for high power application. To verify the effectiveness of the LCLC converter for hold-up operation, comprehensive analysis has been conducted; a detailed step by step design example based on capacitor voltage stress is introduced; an experimental LCLC prototype optimized at 400 V, with input voltage range of 250–400 V and 12 V/500 W as output has been presented. [ABSTRACT FROM AUTHOR]

Published

2019

173. A Single-Stage Capacitive AC-Link AC–AC Power Converter.

Author

Afshari, Ehsan, Khodabandeh, Masih, and Amirabadi, Mahshid

Subjects

*THREE-phase alternating currents, *SINGLE-stage accelerators, *CASCADE converters, *CAPACITORS, *ENERGY transfer

Abstract

A single-stage three-phase ac–ac converter benefiting from a high-frequency alternating link voltage is proposed in this paper. In this converter, a very small film capacitor can transfer the energy from the input to the output, owing to the high-frequency alternating voltage of the link. This eliminates the need for large electrolytic capacitors that are typically used in dc-link ac–ac converters. Moreover, a compact high-frequency transformer at the link can replace the bulky low-frequency transformers, in case isolation is required. These features increase the power density as well as reliability of the proposed converter in comparison with the conventional dc-link converters. The number of required switches in the proposed converter is 12, which is less than the number of switches needed in matrix converters, leading to lower switching and conduction losses. Despite being single-stage, the proposed ac–ac converter is capable of both stepping up and stepping down the voltage and also frequency transformation. This eliminates the need for using cascaded power converters. In this paper, the operation principles of the proposed ac–ac converter are investigated, and variable switching frequency and fixed switching frequency control methods for operating this converter are introduced. The performance of the converter is verified through simulation and experiment. [ABSTRACT FROM AUTHOR]

Published

2019

174. Comments on “Digital Current Control in a Rotating Reference Frame—Part I: System Modeling and the Discrete Time-Domain Current Controller With Improved Decoupling Capabilities”.

Author

Busada, Claudio Alberto, Jorge, Sebastian Gomez, and Solsona, Jorge A.

Subjects

*ROTORS (Helicopters), *TIME-domain analysis, *MATHEMATICAL decoupling, *DISCRETE-time systems, *ELECTRIC currents

Abstract

A recent paper by Hoffmann et al. presents a discrete-time model in a rotating $dq$ reference frame of an R-L filter and its current control. The purpose of this note is, first, to show that the discrete model presented in the paper behaves differently to the sampled continuous-time model of the plant, formulated in the stationary $\alpha \beta$ reference frame; second, to find the proper discretization of the plant in $dq$ coordinates; and third, to verify that there is cross coupling between axes $d$ and $q$ in the closed-loop system if the original model is used, and that this coupling is not present when using the model found in this note. In the note, it is verified that having a precise model of the plant allows us to fulfill the control objective of obtaining the complete decoupling between axes. [ABSTRACT FROM AUTHOR]

Published

2019

175. Multiresonant Power Converter for Improved Dual-Frequency Induction Heating.

Author

Sarnago, Hector, Lucia, Oscar, and Burdio, Jose M.

Subjects

*ENERGY conversion, *INDUCTION heating, *ENERGY consumption, *CONVERTERS (Electronics), *COST effectiveness

Abstract

Industrial induction heating (IH) is a key manufacturing process due to its benefits in terms of efficiency, accurate output power control, and high performance. These features have made possible the extension of this technology to a wide range of industries from automotive to aeronautic, domestic, or renewable energies. One of the main challenges still present is the design of a high-performance and cost-effective process for those induction targets with complex geometries exposed to the magnetic field, being the most representative example gears present in most mechanical systems. Usually, in order to optimize the heating process, multifrequency IH systems are used, being often expensive and/or difficult to tune and control. The aim of this paper is, consequently, to propose a family of power converters able to supply the inductor system with two simultaneous frequencies in order to improve the heating process of the induction target. The proposed converter takes advantage of a multiresonant network allowing full control of the output power delivered at each frequency and, at the same time, a compact and cost-effective implementation. The proposed converter is analyzed, designed, and implemented, and experimental verification of its operation is provided in this paper. [ABSTRACT FROM AUTHOR]

Published

2019

176. Extended Topology for a Boost DC–DC Converter.

Author

Shahir, Farzad Mohammadzadeh, Babaei, Ebrahim, and Farsadi, Murtaza

Subjects

*TOPOLOGY, *CASCADE converters, *ELECTRIC inductance, *PROTOTYPES, *HIGH voltages

Abstract

In this paper, a new structure for a nonisolated boost dc–dc converter is proposed. The proposed converter generates higher voltage gain than some conventional nonisolated boost dc–dc converters. In this paper, the voltage and current equations of the elements and voltage gain in continuous conduction mode and discontinuous conduction mode are extracted. Then, the critical inductance converter is extracted and the current stresses in the switches are calculated. To achieve high voltage gain, a generalized structure based on the proposed structure generates for dc–dc converters. Meanwhile, the root mean square current relations of devices are obtained for an extended structure. Finally, the results of PSCAD/EMTDC software and laboratory prototype are used to reconfirm theoretical concept. [ABSTRACT FROM AUTHOR]

Published

2019

177. A New Hybrid Multilevel DC–AC Converter With Reduced Energy Storage Requirement and Power Losses for HVDC Applications.

Author

Yang, Jie, He, Zhiyuan, Ke, Jinkun, and Xie, Minhua

Subjects

*HYBRID systems, *DC-AC converters, *ENERGY storage, *HIGH-voltage direct current transmission, *BIPOLAR transistors

Abstract

A dc–ac converter for voltage-source converter (VSC)-HVdc technology has a significant influence on the performance of the entire power transmission system. This paper introduces a new dc–ac converter composed of submodules and series insulated-gate bipolar transistor (IGBT) switches. The basic idea of this hybrid solution is to shape the ac voltage by submodules but, per half cycle, reconnect them to different electrical points by IGBT switches. This concept can help to reduce the quantities of submodules, thereby reducing the energy storage requirement significantly. Another advantage is that the IGBT switches can be soft switched by utilizing the high controllability of the submodules. This brings extra benefit of power losses reduction. In this paper, the operating principle of this hybrid converter is explained. Its performances are also presented in detail and compared with those popular VSC dc–ac converters. The feasibility of the new concept is also verified by simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

178. Improving the Third Quadrant Operation of Superjunction MOSFETs by Using the Cascode Configuration.

Author

Rodriguez, Juan, Lamar, Diego G., Roig, Jaume, Rodriguez, Alberto, and Bauwens, Filip

Subjects

*METAL oxide semiconductor field-effect transistors, *LOW voltage systems, *BAND gaps, *PHYSICS experiments, *TRANSISTORS

Abstract

In this paper, the third quadrant behavior of a high-voltage superjunction mosfet (SJ-FET) in cascode configuration (CC) with a low-voltage silicon mosfet is deeply studied by means of an analytical model and experimental data. The third quadrant dynamic behavior of the SJ-CCs is compared to the standalone counterparts by evaluating their reverse recovery time (tRR), reverse recovery peak current (IRRM), and reverse recovery charge (QRR). An analytical model and experimental results show that the SJ-CC avoids or mitigates the activation of the SJ-FET body diode during the third quadrant operation. As a consequence, the SJ-CC strongly improves the widely used figure-of-merit RON·QRR, which considers the on-state resistance of the transistors (RON). In addition, the results obtained using an SJ-CC are similar or better than those achieved by SJ-FETs with enhanced reverse recovery (i.e., irradiated SJ-FETs). This paper also includes a comparison with commercial wide bandgap switches, concluding that the RON·QRR value provided by the SJ-CC is around eight times higher than that provided by a commercial GaN cascode. [ABSTRACT FROM AUTHOR]

Published

2019

179. Instantaneous Balancing of Neutral-Point Voltages for Stacked DC-Link Capacitors of a Multilevel Inverter for Dual-Inverter-Fed Induction Motor Drives.

Author

Yadav, Apurv Kumar, Gopakumar, K., R, Krishna Raj, Umanand, Loganathan, Matsuse, Kouki, and Kubota, Hisao

Subjects

*ELECTRIC potential, *DIRECT currents, *CAPACITORS, *ELECTRIC inverters, *INDUCTION motors

Abstract

This paper proposes a novel method for instantaneous balancing of neutral-point (NP) voltages with stacked multilevel inverters (MLIs) for variable-speed drives. The stacked MLI uses series-connected dc sources and NPs (connecting points of dc sources) to obtain the desired levels. The balancing of NP voltages are obtained by using a low-voltage-capacitor-fed cascaded H-bridge (CHB) per phase of a symmetrical six-phase induction machine (IM), which ensures zero current drawn from NPs (at any given instant). Since no current is drawn from NPs, the single dc-link operation with stacked capacitors is also possible. The scheme is suitable for applications, where low-voltage dc sources and batteries are stacked to form a dc link. A variable-speed operation is done using a seven-level inverter scheme for a symmetrical six-phase IM, which is formed by three dc-link stacked capacitors cascaded with two low-voltage-capacitor-fed CHBs per phase. Furthermore, the method is extended for an open-end IM to obtain a seven-level common-mode eliminated space vector structure using a single dc link. The generalization of this method for any stacked $n$ -level inverter without NP voltage deviation is also presented in this paper. The experimental results and analysis are included to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

180. Active Cross-Correlation Anti-Islanding Scheme for PV Module-Integrated Converters in the Prospect of High Penetration Levels and Weak Grid Conditions.

Author

Voglitsis, Dionisis, Papanikolaou, Nick Peter, and Kyritsis, Anastasios Ch.

Subjects

*CROSS correlation, *PHOTOVOLTAIC cells, *CONVERTERS (Electronics), *PENETRATION mechanics, *DISCRETE Fourier transforms

Abstract

This paper introduces a new cross-correlation anti-islanding detection scheme for module-integrated converters (MICs) with pseudo dc-link. The proposed scheme periodically injects a second-order harmonic current component of low magnitude (in open-loop mode) and evaluates grid response by means of correlation. The proposed scheme is highly reliable, providing nondetection-zone free operation, fast detection, and compliance with the relevant power quality and anti-islanding standards. Additionally, it excels in lower computational cost, reduced fault detection zone, and higher output power quality, compared to the referenced anti-islanding schemes that are compatible with MICs. Last but not least, it can be implemented in MIC platforms without requiring an output current sensor, being an easily upgradable solution in software level. A firm theoretical framework that considers both high penetration levels of PV systems and weak grid conditions is also included in this paper. The theoretical framework, as well as the effectiveness of the proposed scheme, is verified through extensive experimental results for various electrical-network parameters and nonlinear loading conditions. Finally, a comprehensive comparison between the proposed method and the most common anti-islanding techniques (compatible with MICs) is performed, leading to some valuable conclusions from MICs perspective. [ABSTRACT FROM AUTHOR]

Published

2019

181. A Reduced Switch Hybrid Multilevel Unidirectional Rectifier.

Author

Mukherjee, Debranjan and Kastha, Debaprasad

Subjects

*HYBRID systems, *PULSE width modulation transformers, *TELECOMMUNICATION, *ENERGY conversion, *PHASE transitions

Abstract

Nonregenerative pulsewidth-modulated (PWM) rectifiers are increasingly being considered for applications, where the power flow is unidirectional, such as power supplies for telecommunications, X-ray, the machine-side converter for wind energy conversion systems, etc. They use fewer active switches, which increase their power density and reduce cost. This paper proposes a novel reduced switch topology for a multilevel (five-level or higher) nonregenerative PWM rectifier. It uses only four controlled switches and eight diodes per phase for a five-level rectifier. Half of the diodes are naturally commutated (zero current switching) at the line frequency, which reduces switching losses. This topology has several other advantages compared to similar topologies reported in the literature, such as minimum voltage stress across the devices, elimination of transient voltage-balancing snubbers, no extra hardware for balancing the flying capacitors, the dc-link mid-point voltage, etc. In this paper, switching cycle average modeling and the carrier-based modulation strategy for this rectifier are also presented to maintain a balanced dc link and to regulate flying capacitor voltages, while achieving unity displacement factor at the rectifier input terminals. The overall performance of the rectifier is verified by experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

182. Model Predictive Current Control for PMSM Drives With Parameter Robustness Improvement.

Author

Zhang, Xiaoguang, Zhang, Liang, and Zhang, Yongchang

Subjects

*PREDICTIVE control systems, *ROBUST control, *MAXIMUM power point trackers, *PULSE width modulation transformers, *INDUCTIVE power transmission

Abstract

In order to solve the parameter dependence problem in model predictive control, an improved model predictive current control (MPCC) method based on the incremental model for surface-mounted permanent-magnet synchronous motor drives is proposed in this paper. First, the parameter sensitivity of a conventional MPCC method is analyzed, which indicates that the parameter mismatches would cause prediction current error and inaccurate delay compensation. Therefore, an incremental prediction model is introduced in this paper to eliminate the use of permanent magnetic flux linkage in a prediction model. Among the parameter of the incremental prediction model, only inductance mismatch contributes to the prediction error, since the influence of resistance mismatch on the control performance is very small. Therefore, in order to improve the antiparameter-disturbance capability of the MPCC method, an inductance disturbance controller, which includes the inductance disturbance observer and inductance extraction algorithm, is presented to update accurate inductance information for the whole control system in real time. Finally, simulation and experimental results both show that the proposed method can effectively eliminate the influence of the parameter mismatches on the control performance and reduce the parameter sensitivity of the MPCC method. [ABSTRACT FROM AUTHOR]

Published

2019

183. An Improved Torque Sharing Function for Torque Ripple Reduction in Switched Reluctance Machines.

Author

Li, Haoding, Bilgin, Berker, and Emadi, Ali

Subjects

*RELUCTANCE motors, *INDUCTIVE power transmission, *ELECTRIC current converters, *PULSE width modulation transformers, *RESONANT inverters

Abstract

An offline torque sharing function (TSF) is introduced in this paper for torque ripple reduction in switched reluctance machines (SRM). This TSF uses static flux linkage characteristics of the machine obtained from finite element analysis or experiments that describe the machine dynamics to determine optimal current profiles such that the torque ripple reduction is achieved with minimal copper losses. Due to this feature, the proposed TSF performs well across a wide speed range. Additionally, the objective function of the proposed TSF uses only one weight parameter, which facilitates the use of this TSF. In this paper, an intuitive justification for the selection of this weight parameter is given, and the performance of this TSF is validated in simulation and experimentally on a 5.2 kW, four phase SRM. To baseline its performance, the proposed TSF has been compared to the offline TSF in the literature, which shows that it has better current tracking performance at higher speeds due to the inclusion of flux linkage characteristics. Finally, it has been compared to conduction angle control at speeds above the base speed to show that it can be a viable alternative for the control of SRM even in an operation region normally not considered for TSF. [ABSTRACT FROM AUTHOR]

Published

2019

184. Comments on “A Single-Inductor Multiple-Output Switcher With Simultaneous Buck, Boost, and Inverted Outputs”.

Author

Abbasi, Majid, Afifi, Ahmad, and Pahlavani, Mohamad Reza Alizadeh

Subjects

*ELECTRIC current converters, *PULSE width modulation transformers, *ELECTRIC leakage, *ELECTRIC controllers, *RESONANT inverters

Abstract

In the paper by Patra et al., a single-inductor multiple-output switcher was presented to produce buck, boost, and inverted outputs simultaneously. Unfortunately, this study showed some unexpected mistakes, especially in state-space equations and in the calculation of output voltages. The objective of this note was to provide correct analysis and rectify the errors in this paper. Some tables and equations have been modified that were present in the initial draft of this paper. The obtained parameters in this work could be an effective supplement and extension for the original work in the paper by Patra et al. [ABSTRACT FROM AUTHOR]

Published

2019

185. Performance Evaluation of High-Power SiC MOSFET Modules in Comparison to Si IGBT Modules.

Author

Zhang, Lei, Yuan, Xibo, Wu, Xiaojie, Shi, Congcong, Zhang, Jiahang, and Zhang, Yonglei

Subjects

*METAL oxide semiconductor field-effect transistors, *SILICON carbide, *INSULATED gate bipolar transistors, *ELECTRIC current converters, *PULSE width modulation transformers

Abstract

The higher voltage blocking capability and faster switching speed of silicon-carbide (SiC) mosfets have the potential to replace Si insulated gate bipolar transistors (IGBTs) in medium-/low-voltage and high-power applications. In this paper, a state-of-the-art commercially available 325 A, 1700 V SiC mosfet module has been fully characterized under various load currents, bus voltages, and gate resistors to reveal their switching capability. Meanwhile, Si IGBT modules with similar power ratings are also tested under the same conditions. From the test results, several interesting points have been obtained: different to the Si IGBT module, the over-shoot current of the SiC mosfet module increases linearly with the increase of the load current and it has been explained by a model of the over-shoot current proposed in this paper; the induced negative gate voltage due to the complementary device turn-off (crosstalk effect) is more harmful to the SiC mosfet module than the induced positive gate voltage during turn-on when the gate off-voltage is –6 V; the maximum dv/dt and di/dt (electromagnetic interference) during switching transients of the SiC mosfet module are close to those of the Si IGBT module when the gate resistance is larger than 8 Ω but the switching loss of the SiC mosfet module is much smaller; the switching losses of the Si IGBT module are greater than those of the SiC mosfet module even when the gate resistance of the former is reduced to zero. An accurate power loss model, which is suitable for a three-phase two-level converter based on SiC mosfet modules considering the power loss of the parasitic capacitance, has been presented and verified in this paper. From the model, a 96.2% efficiency can be achieved at the switching frequency of 80 kHz and the power of 100 kW. [ABSTRACT FROM AUTHOR]

Published

2019

186. Direct Predictive Current-Error Vector Control for a Direct Matrix Converter.

Author

Vijayagopal, Manjusha, Silva, Cesar, Empringham, Lee, and de Lillo, Liliana

Subjects

*VECTOR control, *ELECTRIC current converters, *PULSE width modulation transformers, *ELECTRIC leakage, *ELECTRIC controllers

Abstract

This paper proposes a novel control strategy for matrix converters that is coined “direct predictive current-error vector control.” The proposed control method retains the advantageous features of both a modulation scheme and of a predictive-based controller. The result is a controller that is capable of good dynamic performance and steady-state response with fixed switching frequency operation. Control of load and input currents of a direct matrix converter using the proposed method is demonstrated in this paper by simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2019

187. A Unidirectional Single-Stage Three-Phase Soft-Switched Isolated DC–AC Converter.

Author

Pal, Anirban and Basu, Kaushik

Subjects

*DC-AC converters, *PULSE width modulation transformers, *SINE waves, *HIGH frequency transformers, *ZERO voltage switching, *ELECTRIC leakage

Abstract

This paper presents a novel single-stage soft-switched high-frequency-link three-phase dc–ac converter topology. The topology supports unidirectional dc to ac power flow and is targeted for applications like grid integration of photovoltaic sources, fuel cell, etc. The high frequency magnetic isolation results in reduction of system volume, weight, and cost. Sine-wave pulsewidth modulation is implemented in dc-side converter. Though high-frequency switched, dc-side converter is soft switched for most part of the line cycle. The ac-side converter active switches are line frequency switched incurring negligible switching loss. The line frequency switching of ac-side converter facilitates use of high voltage blocking inherently slow semiconductor devices to generate high voltage ac output. In addition, a cascaded multilevel structure is presented in this paper for direct medium-voltage ac grid integration. A detailed circuit analysis considering nonidealities like transformer leakage and switch capacitances, is presented in this paper. A 6-kW three-phase laboratory prototype is built. The presented simulation and experimental results verify the operation of the proposed topologies. [ABSTRACT FROM AUTHOR]

Published

2019

188. Optimal Three-Dimensional Current Computation Flux Weakening Control Strategy for DC-Biased Vernier Reluctance Machines Considering Inductance Nonlinearity.

Author

Yu, Zixiang, Kong, Wubin, Qu, Ronghai, Li, Dawei, Jia, Shaofeng, Jiang, Dong, Sun, Jianbo, and Li, Hongtao

Subjects

*VOLTAGE control, *PERMANENT magnet motors, *FINITE element method, *ELECTRIC inductance, *PROTOTYPES

Abstract

An optimal three-dimensional current computation flux weakening control strategy for dc-biased Vernier reluctance machines (VRMs) is proposed in this paper. Compared with permanent magnet synchronous machines, dc-biased VRMs have an additional degree of freedom to regulate the rotor flux through variable dc-biased armature current. The conventional flux weakening control strategy does not utilize the adjustable dc field current, and the output capacity in the flux weakening region is limited. In this paper, the optimal three-dimensional current distribution is calculated at the intersection of current and voltage constraint. Meanwhile, in order to maintain the armature voltage within the voltage constraint, the inductance nonlinearity is reflected by constructing the inductance table. The algorithm provides maximum output capability and high efficiency for dc-biased VRMs despite the changes in inductance parameters in the whole flux weakening region. Finally, the effectiveness of the proposed control strategy is validated by experimental results for a prototype machine. [ABSTRACT FROM AUTHOR]

Published

2019

189. Commutation Behavior Analysis of a Dual 3L-ANPC-VSC Phase-Leg PEBB Using 4.5-kV and 1.5-kA HV-IGBT Modules.

Author

Mayor, Alvar, Rizo, Mario, Rodriguez Monter, Ana, and Bueno, Emilio J.

Subjects

*VOLTAGE-frequency converters, *SEMICONDUCTOR devices, *SYNCHRONOUS capacitors, *SWITCHING power supplies, *FINITE element method

Abstract

Three-level neutral-point clamped voltage source converter (3L-NPC-VSC) is widely used in high-power and medium-voltage (MV) applications and the most used multilevel VSC topology. 3L-Active-NPC-VSC (3L-ANPC-VSC) was introduced to overcome the unequal losses distribution as main structural drawback of the 3L-NPC-VSC. During the switching event of semiconductor devices, the stray inductance takes a special role in the commutation path of the switching current. Mutual coupling inductance between the components participating in the commutation path has to be considered for a theoretical assessment of the total stray inductance of each commutation path. Besides, the measurement of the commutation path stray inductance has to be carried out during the turn-on of the semiconductor device, instead of during the turn-off, to consider the reverse blocking voltage of the opposite switching semiconductor device. This paper shows how a dual 3L-ANPC-VSC phase-leg has been carefully designed and assembled to build a ±10 MVAr five-level VSC for MV-static synchronous compensator applications. The minimization of the stray inductance, the equalization of the total switching power losses for all commutation paths and power density maximization with snubberless operation are within the main technical design requisites. On the basis of the theoretical analysis, the stray inductance of all the commutation paths has been extracted, considering mutual coupling effect, by means of three-dimensional finite-element-analysis simulations. Once the design concept is theoretically validated, the estimated values have been compared with the experimental results obtained from the performance of double-pulse tests for each commutation path. This paper presents, for the first time, all the analysis details of the 3L-ANPC-VSC commutation behavior using 4.5-kV and 1.5-kA trench high-voltage insulated-gate bipolar transistor modules. [ABSTRACT FROM AUTHOR]

Published

2019

190. Direct Digital Control of Single-Phase Grid-Connected Inverters With LCL Filter Based on Inductance Estimation Model.

Author

Wu, Tsai-Fu, Misra, Mitradatta, Jhang, Ying-Yi, Huang, Yen-Hsiang, and Lin, Li-Chiun

Subjects

*DIGITAL control systems, *ELECTRIC inverters, *ELECTRIC inductance, *POWDER cores (Magnetic materials), *MAGNETIC permeability

Abstract

Soft magnetic powder cores with their high saturation flux density and low core loss are excellent alternatives for filter inductors in inverter-based applications. However, their nonlinear current-dependent inductance characteristics pose a challenge for control of grid-connected inverter with LCL filter. In this paper, the variable inductance conundrum is discussed and a modified direct digital control method based on a variable-structure inductance estimation model that takes into consideration wide nonlinear variation in both inverter- and grid-side inductances is proposed. The proposed method is shown to have better grid-voltage harmonic rejection and improved stability margins. However, investigation of stability which is conventionally based on nominal values of filter inductors cannot predict instabilities over the entire range of inductance variation. Hence, a parametric approach to conventional stability methods with a parameter space defined by variation in actual and estimated inductance is explored in this paper. The effect of line impedance on stability is also investigated with impedance-based stability criterion by considering line inductance as an additional dimension in the parameter space. A pattern in stability margins is observed due to inductance variation, with inductance at its minimum being most vulnerable to instability. Experimental results measured from a 5 kW single-phase grid-connected inverter with various LCL filters have verified the feasibility of the proposed control method. The experimental results also match the analytical results with reasonable accuracy. [ABSTRACT FROM AUTHOR]

Published

2019

191. A Load Impedance Specification of DC Power Systems for Desired DC-Link Dynamics and Reduced Conservativeness.

Author

Pidaparthy, Syam Kumar, Choi, Byungcho, and Kim, Yeonjung

Subjects

*DIRECT current power transmission, *ELECTRIC impedance, *TRANSIENT responses (Electric circuits), *CASCADE converters, *VOLTAGE control

Abstract

This paper proposes a new load impedance specification for multistage dc power conversion systems. The proposed specification avoids drawbacks of the existing specifications, such as the lack of explicit connections to the dc-link dynamics and the unnecessary conservativeness. The new specification offers a direct command/supervision of the frequency- and time-domain dynamics of the intermediate dc link, while being less conservative than the existing specifications. This paper also presents procedures for redesigning ill-conditioned load impedances to comply with the specification. The validity and utility of the proposed specification are demonstrated using an experimental two-stage dc power conversion system. [ABSTRACT FROM AUTHOR]

Published

2019

192. DFIG Topologies for DC Networks: A Review on Control and Design Features.

Author

Marques, Gil D. and Iacchetti, Matteo Felice

Subjects

*INDUCTION generators, *POWER electronics, *FIELD orientation principle, *MICROGRIDS, *PERMANENT magnet generators

Abstract

The doubly fed induction machine has been traditionally adopted in adjustable-speed ac power generation drives in order to take advantage of the reduced rating for the power electronic interface. Aside this well-established application where the doubly fed induction generator (DFIG) is controlled by a back-to-back converter, recent literature records a growing interest toward un-conventional DFIG drives for dc power generation, combining DFIG high control freedom with simplified power electronic interfaces to achieve an overall cheap and fully controllable system. Despite several concepts have been demonstrated on small-scale rigs, there is a lack of systematic comparison among different topologies and control solutions. This paper bridges this gap by providing a review of recent topologies, their control, design and performance, and operation issues. As major novelties, this paper includes off-spec performance comparison of different torque-ripple mitigation strategies, discussion of sizing requirements for generator and power electronics, fundamental aspects of the behavior under voltage dips, and priorities and challenges for future research on the subject. [ABSTRACT FROM AUTHOR]

Published

2019

193. Gate Control Optimization of Si/SiC Hybrid Switch for Junction Temperature Balance and Power Loss Reduction.

Author

Wang, Jun, Li, Zongjian, Jiang, Xi, Zeng, Cheng, and Shen, Z. John

Subjects

*METAL oxide semiconductor field-effect transistors, *ELECTRIC potential, *ZERO voltage switching, *THERMAL conductivity, *ELECTRIC fields

Abstract

The hybrid switch concept of paralleling a higher-current main Si IGBT and a lower-current auxiliary SiC mosfet offers an improved cost/performance tradeoff in power converters. Currently, the gate control strategy of these two internal devices emphasizes on minimizing the total power loss, and is referred to as the efficiency control mode in this paper. However, there is a serious risk of overheating and reliability degradation of the SiC mosfet if solely relying on this control strategy. In this paper, we propose a new method of gate control optimization, referred to as the thermal balance control mode, to keep the junction temperature of both devices within the specified temperature range, and to minimize the total power loss simultaneously. We first investigate the dependency of the hybrid switch switching losses on the gate control pattern both theoretically and experimentally. We then extensively study control optimization in these two distinct control modes in a dc–dc boost converter. It is found that the thermal balance control mode can achieve almost the same total power loss as the efficiency control mode, but much lower and more balanced junction temperatures of the two internal devices. Experimental results demonstrate that the Si/SiC hybrid switch in an optimal thermal balance control mode can achieve a 163% higher power handling capability in the 20-kHz boost converter or four times higher switching frequency in the 4-kW boost converter than a single IGBT solution with hard switching condition, and yet a considerably lower component cost than a single SiC mosfet solution in the boost converter. [ABSTRACT FROM AUTHOR]

Published

2019

194. 7.2-kV Single-Stage Solid-State Transformer Based on the Current-Fed Series Resonant Converter and 15-kV SiC mosfets.

Author

Zhu, Qianlai, Wang, Li, Huang, Alex Q., Booth, Kristen, and Zhang, Liqi

Subjects

*ELECTRIC transformers, *METAL oxide semiconductor field-effect transistors, *ZERO voltage switching, *VOLTAGE control, *ENERGY storage equipment

Abstract

This paper proposes a novel two-level single-stage direct ac–ac converter for realizing a 7.2-kV medium-voltage (MV) solid-state transformer (SST) based on 15-kV SiC mosfets. A new current-fed series resonant converter (CFSRC) topology is proposed to address major challenges in MV ac–ac converters such as achieving zero-voltage switching (ZVS) for the MV mosfets across wide voltage and load ranges and minimizing system capacitance. The topology is analyzed with both time-domain analysis and first harmonic approximation to provide useful equations for circuit design. Constant deadtime strategy is adopted, allowing partial ZVS to occur at low-voltage (LV) levels. ZVS behavior over wide voltage range is investigated, and calculation of the associated loss from partial ZVS is presented. System parameters are optimized based on the tradeoff between conduction loss and switching loss. The 15-kV mosfet has been tested continuously at a park voltage of 10 kV and 37 kHz, indicating stable device operation and an extremely high voltage × frequency figure of merit. Moreover, inherent cycle-by-cycle current limiting in the proposed CFSRC under output short-circuit circumstance is realized by paralleling diodes to the LV resonant capacitors. Without employing any additional current sensors, the input and circulating currents are limited to a safe range automatically when the short-circuit occurs. This paper presents detailed short-circuit protection operating principles and peak resonant current equation to aid the design of the resonant tank. A full-scale and compact SST that converts 7.2 kV ac to 240 V ac is developed to verify the theoretical analysis. This is the highest reported voltage rating for two-level-based power converters without device series connection. ZVS is verified and achieved over wide voltage and load ranges with a peak efficiency of 97.8%. A short-circuit experiment is conducted at 3-kV peak voltage to verify the analysis. Experimental results closely match the theoretical analysis. [ABSTRACT FROM AUTHOR]

Published

2019

195. Ultralow Input–Output Capacitance PCB-Embedded Dual-Output Gate-Drive Power Supply for 650 V GaN-Based Half-Bridges.

Author

Sun, Bingyao, Burgos, Rolando, and Boroyevich, Dushan

Subjects

*ELECTRIC capacity, *POWER resources, *MODULATION-doped field-effect transistors, *PRINTED circuits, *GALLIUM nitride

Abstract

Wide-bandgap devices have been widely used to reduce the size and increase the efficiency of power converters by operating at a high switching frequency, at the expense of heightened radiated and conducted electromagnetic inference (EMI) emissions, of which the latter circulates through the power loop and ancillary circuitry. In effect, the parasitic isolation capacitance $C_{i}$ of the gate-driver power supply represents a key EMI propagation path to be controlled in order to ensure the operational integrity of power converters. To this end, this paper proposes an integrated, dual-output gate-drive power supply for gallium-nitride (GaN) 650 V, 60 A, half-bridge phase legs, rated at 2 W (2 × 1 W), 15 to 2 × 7 V, featuring an ultralow $C_{i}$ of 1.6 pF, an output-to-output parasitic capacitance of 1.6 pF, a power density of 72 W/in3, and an efficiency of 85%. All this is attained using an active-clamp flyback converter switching at 1 MHz using 65 V GaN high-electron-mobility transistor devices and Schottky output rectifiers, and a Pareto-optimized transformer design minimizing its interwinding capacitances, volume, and losses. Finally, the transformer is fully embedded in a printed circuit board (PCB) material, doubling as a substrate for the topside active layer of the power supply. The paper presents the complete design procedure, processing, and experimental demonstration of the proposed integrated power supply, evaluating as well the reliability impact of the magnetic-PCB material interface in high ambient temperature applications (>200 °C). [ABSTRACT FROM AUTHOR]

Published

2019

196. An Online Monitoring Method of Circuit Parameters for Variable On-Time Control in CRM Boost PFC Converters.

Author

Ren, Xiaoyong, Wu, Yu, Guo, Zhehui, Zhang, Zhiliang, and Chen, Qianhong

Subjects

*ONLINE monitoring systems, *ZERO voltage switching, *ELECTRIC power factor, *HARMONIC distortion (Physics), *DIGITAL control systems

Abstract

This paper proposes an improved zero current detection for critical conduction mode (CRM) control, which can compensate the input current distortion caused by the signal propagation delay and the existence of the negative resonance current. A unified variable on-time calculation method is also proposed to unify the formulas under the zero-voltage-switching condition and the valley-switching condition. Since these two methods are dependent on the boost inductance and device junction capacitance, which may be different from the nominal values, effort is needed to compensate the deviation on these two parameters. In this paper, an online monitoring method is proposed to compensate the numerical deviation. The proposed method only needs to sense the input voltage, output voltage, and the reverse flow time of the inductor current, leading to a high power quality in the entire input and load conditions. The experimental results of the proposed methods are demonstrated on a 200-W GaN-based CRM boost power factor correction prototype. With the proposed methods, the input current total harmonic distortion is only 0.78% at 110 VAC input with full load and 2.1% at 220 VAC input with full load. [ABSTRACT FROM AUTHOR]

Published

2019

197. A Current-Mode Buck Converter With Reconfigurable On-Chip Compensation and Adaptive Voltage Positioning.

Author

Chen, Ching-Jan, Lu, Shao-Hung, Hsiao, Sheng-Fu, Chen, Yung-Jen, and Huang, Jian-Rong

Subjects

*ELECTRIC potential, *INTEGRATED circuits, *CONVERTERS (Electronics), *ANALOG-to-digital converters, *ELECTRIC circuits

Abstract

Power management integrated circuits (PMICs) with on-chip compensation are widely used to power multiple loads in mobile devices with increased power density. However, there are two issues for on-chip compensated PMICs. First, on-chip compensation reconfigurability is required to obtain the appropriate response in various passive components. Second, a converter for a processor requires adaptive voltage positioning (AVP) to reduce the output capacitor size. In this paper, a novel reconfigurable on-chip compensated current-mode buck converter with AVP is proposed to solve the aforementioned issues without requiring high-speed and high-resolution analog-to-digital converter (ADC). A reconfigurable accurate load line control scheme and on-chip compensation are proposed to achieve an accurate load line and AVP in various load lines and passive components. The control scheme, small-signal model, and circuit implementation are illustrated in this paper. The proposed buck converter was implemented into an integrated circuit to verify the analysis. [ABSTRACT FROM AUTHOR]

Published

2019

198. Inner Supply Data Transmission in Quasi-Resonant Flyback Converters for Li-Ion Battery Applications Using Multiplexing Mode.

Author

Min, Geon-Hong and Ha, Jung-Ik

Subjects

*MULTIPLEXING, *DATA transmission systems, *LITHIUM-ion batteries, *BATTERY chargers, *ELECTRIC potential, *CONVERTERS (Electronics)

Abstract

This paper proposes data transmission method between primary and secondary of the flyback converter without additional communication circuit while simultaneously transferring power. In some application such as a battery charger, the data exchanges between the primary and secondary sides are necessary. In the conventional system, an additional line or wireless communication modules is used for data exchanges, thereby increasing the system and connector size. The proposed system, in comparison, does not use additional signal transceiver but instead exchanges data by simply alternating operation mode of the flyback converter, thus adding communication function while not increasing the volume of the terminal and overall system. The waveform of transformer voltage is used to count the number of resonant pulses, which is used for decoding and encoding the data packet. Bidirectional communication between primary and secondary sides is possible while power is transferred to the output using an appropriate communication protocol. This paper proposes data transmission method for both single output and the multioutput cases. Also, both half-duplex and full-duplex communication using the proposed method is explained. The experimental results are presented to verify the performance of the proposed communication method. [ABSTRACT FROM AUTHOR]

Published

2019

199. A High-Efficiency Single-Phase T-Type BCM Microinverter.

Author

Zhang, Zhen, Zhang, Junming, Shao, Shuai, and Zhang, Junjun

Subjects

*ELECTRIC inverters, *LOAD flow analysis (Electric power systems), *ELECTRIC potential, *TRANSISTORS, *ELECTRIC power distribution grids

Abstract

This paper proposes a high-efficiency single-phase T-type boundary conduction mode (BCM) microinverter. The conventional full-bridge BCM microinverter has achieved zero voltage switching (ZVS) and thereby improved the efficiency, but it suffers from high switching losses under light load conditions. The proposed T-type BCM microinverter reserves ZVS and uses a multilevel technique to further decrease the switching losses. The BCM operation with multilevel technique will have too low switching frequency when the grid voltage approaches half of the dc link voltage. To solve this problem, this paper adopts a third operation mode for the T-type switching leg to maintain the switching frequency above a minimum value. The corresponding mode transitions are also detailed to ensure a smooth operation. Because of the turn-offdelay of the freewheeling transistor, the actual lower current boundary deviates from the programmed one, which will distort output current. To address this issue, this paper also proposes a boundary compensation method. A prototype has been built for performance verification, which can test both full-bridge and T-type topology. Compared with the full-bridge BCM microinverter, the proposed T-type BCM microinverter has a higher efficiency over the whole load range. [ABSTRACT FROM AUTHOR]

Published

2019

200. Performance Evaluation of Series-Compensated IPT Systems for Transcutaneous Energy Transfer.

Author

Knecht, Oliver and Kolar, Johann W.

Subjects

*ENERGY transfer, *HEART assist devices, *ELECTRIC power transmission, *ELECTRIC circuits, *ELECTRIC batteries

Abstract

Today's implantable mechanical circulatory support devices, such as left ventricular assist devices, still rely on a percutaneous driveline, which is a frequent cause of severe infections and which reduces the quality of life for the patients. Inductive power transfer (IPT) is therefore a promising technology to replace the driveline and, hence, reducing the likelihood of an infection. This paper focuses on the series–series compensated IPT system and provides an in-depth comparison of two operating modes, i.e., the operation at resonance and the operation above resonance, and highlights the advantages and disadvantages with respect to the requirements set by the application at hand. In addition, the paper presents the design and the realization of a fully functional transcutaneous energy transfer (TET) implant hardware prototype, which includes the IPT front-end, the control circuit, the backup battery and its charging converter, as well as the communication electronics in a boxed volume of only 10.3 cl. The experimental verification shows that overall dc–dc efficiencies of up to 90% can be achieved for both operating modes when transmitting 25–30 W from the external battery to the implant backup battery, each having a nominal voltage of 14.8 V, using TET coils with 70 mm diameter and 10 mm coil separation distance. [ABSTRACT FROM AUTHOR]

Published

2019