sábado, 19 de fevereiro de 2022
sexta-feira, 11 de fevereiro de 2022
Ph.D. Dissertation Fast Transient and High Efficiency Voltage-Regulated PWM Buck Converters Jung-Duk Suh Department of Electrical and Computer Engineering The Graduate School Sungkyunkwan University 2019
Ph.D. Dissertation Fast Transient and High Efficiency Voltage-Regulated PWM Buck Converters
Jung-Duk Suh
Department of Electrical and Computer Engineering
The Graduate School
Sungkyunkwan University
2019
Abstract
Fast Transient and High Efficiency Voltage-Regulated
PWM Buck Converters
This dissertation proposes three pulse-width modulation (PWM) buck
converter architectures; two for fast load transient and one for high efficiency.
A fast load transient response for small overshoot or undershoot is very
important to designing switching regulator because dynamic voltage scaling is
regarded as an effective power management solution. The transient response
in the conventional voltage mode converter is limited since a type-3
compensator with large capacitors is used. So, it is important to improve slow
transient response problems. Also, improving the efficiency under the light load
condition of switching regulators is a very important design because of many
portable devices stay in standby mode. In common PWM buck converters, the
switching loss is dominant in the light load. So, to improve the performance of
PWM buck converters in terms of the light-load efficiency, the switching power
consumption should be minimized.
In this dissertation, to overcome the speed limitation of the PWM control and
the light load efficiency, PWM buck converters that can improve both the load
transient response and the light load efficiency are proposed. First, a DC-DC
converter with active ramp tracking control (ARTC) is presented. When the
difference between the output voltage and reference voltage is increased to the
threshold voltage in the load transient situation, the ramp bias voltages change
and generate a full duty signal to the power switches. This helps restore the
output voltage to the reference voltage, improving the load transient response
speed and decreasing the overshoot/undershoot at the output voltage. The
proposed converter with ARTC improves the load transient response speed and
decreases the overshoot/undershoot at the output voltage. This proposed buck
converter with ARTC can reduce the overshoot/undershoot at the output by up
to 61.1% and the recovery time up to 60.0 % for a 450-mA load current step.
Second, a DC-DC converter with inductor current slope control (ICSC) is
presented. In load transient period, the slope of the inductor current is increased
two times by connecting the parallel inductor of same size as main inductor. It
can recover the output voltage quickly and have a consistent fast response time
regardless of the load current step size and output voltage. This proposed buck
converter with ICSC simulated in a 65-nm CMOS technology reduces the
overshoot/undershoot at the output by up to 54.4% and the recovery time up to
82.6% for a 450-mA load current step. Third, a DC-DC converter with chargerecycling
gate-voltage swing control is presented. This proposed converter
with charge-recycling gate-voltage swing control can improve the power
efficiency by reducing the gate-driving loss at the light load. This proposed
converter controls the gate-voltage swing with charge-recycling structure
according to the load current and has the gate-driving loss reduced by up to
87.7% and 47.2% compared to the conventional full-swing and low-swing
designs, respectively. The maximum power conversion efficiency was 90.3%
when the input and output voltages are 3.3 V and 1.8 V, respectively.
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domingo, 6 de fevereiro de 2022
Active gate switching control of IGBT to improve efficiency in high power density converters- AUTOR Ghorbani, Hamidreza- Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica Document-Doctoral thesis
Active gate switching control of IGBT to improve efficiency in high power density converters
Thesis submitted in partial fulfilment of the requirement for the PhD degree issued by the Universitat Politècnica de Catalunya, in its Electronic Engineering Program
BY Hamidreza Ghorbani
Director: Dr. Prof. Jose Luis Romeral Martinez
Co-Director: Dr. Eng. Vicent Sala -May 2019
Abstract
Insulated gate bipolar transistor (IGBT) power semiconductors are widely employed in industrial applications. This power switch capability in high voltage blocking and high current-carrying has expanded its use in power electronics. However, efficiency improvement and reducing the size of products is one of main tasks of engineers in recent years. In order to achieve high-density power converters, attentions are focused on the use of fast IGBTs. Therefore, for achieving this desire the trend is designing more effective IGBT gate drivers. In gate drive (GD) controlling, the main issue is maintaining transient behavior of the MOS-channel switch in well condition; when it switches fast to reduce losses. It is well known that fast switching has a direct effect on the efficiency improvement; meanwhile, it is the major reason of appearing electromagnetic interference (EMI) problems in switched-mode power converters. Nowadays the most expectant of an active gate driver (AGD) is actively adjusting the switching transient through simple circuit implementation. Usually its performance is compared with the conventional gate driver (CGD) with fixed driving profile. As a result a proposed AGD has the capability of increasing the switching speed while minimizing the switching stress. Different novel active gate drivers (as feed-forward and closed-loop topologies) have been designed and analysed in this study. To improve the exist trade-off between switching losses and EMI problem, all effective factors on this trade-off are evaluated and considered in proposed solutions. Theoretical developments include proposed controlling methods and simulated efficiency of IGBTs switching control. The efficiency improvement has been pursued with considering EMI study in the proposed active gate controller. Experimental tests have been conducted to verify the design and validate the results. Beside technical aspects, cost study has also considered in the closed-loop GD. The proposed gate drivers are simple enough to allow its use in real industrial applications.
RESUMEN
Los semiconductores de potencia (IGBT) se emplean ampliamente en aplicaciones industriales. La capacidad de este interruptor de bloqueo en alta tensión y conducción de alta corriente ha ampliado su uso en la electrónica de potencia. Sin embargo, la mejora de la eficiencia y la reducción del tamaño de los convertidores de potencia es una de las tareas principales de los ingenieros de diseño. Para lograr convertidores de potencia de alta densidad y eficiencia, se requiere el uso de IGBT rápidos. Por lo tanto, la tendencia es diseñar controladores de puerta para IGBT más efectivos. En el control de la unidad de puerta (GD), el problema principal es mantener el comportamiento transitorio del conmutador del canal MOS bajo control, cuando conmuta a lata frecuencia para reducir las pérdidas. Es bien sabido que la conmutación rápida tiene un efecto directo en la mejora de la eficiencia; Sin embargo, la alta frecuencia de conmutación es la razón principal de la aparición de problemas de interferencia electromagnética (EMI) en los convertidores de potencia de modo conmutado. En la actualidad, la acción más directa para un controlador de puerta activo (AGD) consiste en el ajuste activo del transitorio de conmutación a través de la implementación de un circuito simple. Para evaluar su eficiencia, su rendimiento se compara con el controlador de puerta convencional (CGD) con perfil de conducción fijo. Los resultados muestran que la propuesta de AGD tiene la capacidad de aumentar la velocidad de conmutación mientras minimiza el stress. En este estudio se han diseñado y analizado diferentes controladores de puerta activa novedosos (como topologías de control en avance y de bucle cerrado). Para mejorar el balance existente entre la reducción de pérdidas y los problemas de EMI, todos los factores que afectan a las pérdidas y la EMI se evalúan y se consideran en las soluciones propuestas. Los desarrollos teóricos incluyen el análisis y desarrollo de los métodos de control propuestos, la simulación de la operación del control de conmutación del IGBT, y la validación experimental. Además de los aspectos técnicos de eficiencia y emisiones electromagnéticas, el estudio de costes también se ha considerado en los análisis de AGD. Los resultados muestran que los controladores de puerta propuestos son lo suficientemente eficientes y económicos como para permitir su uso en aplicaciones industriales reales [-]
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Active gate drivers for high-frequency application of SiC MOSFETs by Paredes Camacho, Alejandro Universitat Politècnica de Catalunya. Departament d'Enginyeria Electrònica Doctoral thesis
Abstract
The trend in the development of power converters is focused on efficient systems with high power density, reliability and low cost. The challenges to cover the new power converters requirements are mainly concentered on the use of new switching-device technologies such as silicon carbide MOSFETs (SiC). SiC MOSFETs have better characteristics than their silicon counterparts; they have low conduction resistance, can work at higher switching speeds and can operate at higher temperature and voltage levels. Despite the advantages of SiC transistors, operating at high switching frequencies, with these devices, reveal new challenges. The fast switching speeds of SiC MOSFETs can cause over-voltages and over-currents that lead to electromagnetic interference (EMI) problems. For this reason, gate drivers (GD) development is a fundamental stage in SiC MOSFETs circuitry design. The reduction of the problems at high switching frequencies, thus increasing their performance, will allow to take advantage of these devices and achieve more efficient and high power density systems. This Thesis consists of a study, design and development of active gate drivers (AGDs) aimed to improve the switching performance of SiC MOSFETs applied to high-frequency power converters. Every developed stage regarding the GDs is validated through tests and experimental studies. In addition, the developed GDs are applied to converters for wireless charging systems of electric vehicle batteries. The results show the effectiveness of the proposed GDs and their viability in power converters based on SiC MOSFET devices.
RESUMEN
La tendencia en el diseño y desarrollo de convertidores de potencia está enfocada en realizar sistemas eficientes con alta densidad de potencia, fiabilidad y bajo costo. Los retos para cubrir esta tendencia están centrados principalmente en el uso de nuevas tecnologías de dispositivos de conmutación tales como, MOSFETs de carburo de silicio (SiC). Los MOSFETs de SiC presentan mejores características que sus homólogos de silicio; tienen baja resistencia de conducción, pueden trabajar a mayores velocidades de conmutación y pueden operar a mayores niveles de temperatura y tensión. A pesar de las ventajas de los transistores de SiC, existen problemas que se manifiestan cuando estos dispositivos operan a altas frecuencias de conmutación. Las rápidas velocidades de conmutación de los MOSFETs de SiC pueden provocar sobre-voltajes y sobre-corrientes que conllevan a problemas de interferencia electromagnética (EMI). Por tal motivo, el desarrollo de controladores de puertas es una etapa fundamental en los MOSFETs de SiC para eliminar los problemas a altas frecuencias de conmutación y aumentar su rendimiento. En consecuencia, aprovechar las ventajas de estos dispositivos y lograr sistemas más eficientes y con alta densidad de potencia. En esta tesis, se realiza un estudio, diseño y desarrollo de controladores activos de puerta para mejorar el rendimiento de conmutación de los MOSFETs de SiC aplicados a convertidores de potencia de alta frecuencia.
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sexta-feira, 4 de fevereiro de 2022
Stability improvement and control optimization of isolated two-stage AC-DC-DC converter systems Authors: Feng, Fan -Engineering::Electrical and electronic engineering::Power electronics -Nanyang Technological University
STABILITY IMPROVEMENT AND CONTROL OPTIMIZATION OF ISOLATED TWO-STAGE AC-DC-DC CONVERTER SYSTEMS by FENG FAN
School of Electrical & Electronic Engineering -2020
A thesis submitted to the Nanyang Technological University
in partial fulfilment of the requirement for the degree of
Doctor of Philosophy
2020
Abstract: Driven by the ever-increasing energy demand and the desire for carbon footprint reduction, the power industry is under a wave of transformation from the current grid into the smart grid. As the trend of the grid transformation continues, a significantly high penetration level of renewable energy resources, in parallel with other emerging technologies such as the energy storage and electric vehicles, is to be expected. Since many types of renewables and energy storage devices, e.g., solar photovoltaic, batteries and supercapacitors, etc., are treated as DC sources, the multi-stage converter system is usually employed as the interface between the AC grid and DC networks. Specifically, the dual active bridge (DAB)-based two-stage AC-DC-DC converter is highly related to the distributed systems because of its advantages such as the high power density, soft switching properties, galvanic isolation and less passive components. Therefore, the stability and reliability of the two-stage AC-DC-DC converters are at the core of the distributed system operations. However, despite its control benefits, the two-stage AC-DC-DC converter system may suffer instability issues. This thesis aims to investigate and overcome the instability issues of the two-stage AC-DC-DC converter system. First, the existing primary stability criteria and stabilization methods for the non-isolated two-stage converter systems have been reviewed and summarized. The terminal impedances of the sub-converters are useful tools to determine the stability of the two-stage converter systems. The forbidden regions for the voltage-source and current-source systems have been discussed. To satisfy these stability criteria, the terminal impedances of the sub-converters should be modified via passive or active damping methods. The research gap for the isolated two-stage AC-DC-DC converter has been identified as well. To analyze the stability of the DAB-based two-stage AC-DC-DC converter, the full-order impedance model of the DAB converter is derived for the first time in this thesis. Since the high-frequency ac conversion stage of the DAB converter naturally violates the small ripple assumption of the traditional state-space modeling, the generalized averaging approach is applied for the DAB impedance derivation. The derived impedance model can provide fully continuous-time representations that are capable of describing the ac conversion stage of the DAB converter. Furthermore, based on the developed impedance model, the influences of the DAB circuit parameters on the stability of the two-stage converter are analyzed. The analysis results offer instructive implications to fine-tune the design rules of the DAB converters. Bearing the mind that the impedance model of the DAB converter is closely related to the modulation schemes, the impacts of three typical modulation methods on the DAB impedances are analyzed and compared. An interesting phenomenon is found that the open-loop impedances of Single Phase-Shift (SPS)-based and Dual Phase-Shift (DPS)-based DAB converters present the characteristics of the parallel-connected inductor and capacitor, while the open-loop impedance of Cooperative Triple Phase-Shift (CTPS)-based DAB converter presents the resistor characteristics. The optimal modulation scheme in terms of stability performance for the two-stage converter is pointed out. This can help engineers find a more stable modulation scheme of the DAB converter in practical cascaded applications.
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