Your search keyword '"Hybrid Transformer"' showing total 53 results

51. High frequency (MHz) soft switched flyback dc-dc converter using GaN switches and six-layered PCB transformer

Author

Bakar, Muhammad Abu, Bertilsson, Kent, Ambatipudi, Radhika, Bakar, Muhammad Abu, Bertilsson, Kent, and Ambatipudi, Radhika

Abstract

The increased switching losses with increasing switching frequency are the biggest concerns in designing high power density converters. This paper presents the investigation of an energy efficient DC-DC flyback converter in combination with six layered printed circuit board transformer. The recorded efficiency of the low profile transformer for the frequency range of 1-5MHz is 98% at power density of 770W/in3. The proposed converter is characterized for frequencies up to 4MHz by using possible soft switching techniques such as Boundary Mode and Quasi Resonant Mode. The emerging Gallium Nitride (GaN FET) devices are used as power switch. The control is incorporated with Digital Signal Processor (dsPIC) for both the Boundary and Quasi Resonant Modes of operations. The proposed flyback DC-DC converter is tested on a prototype Printed Circuit Board (PCB). The performance of the proposed converter is investigated for the telecom input voltage range of 36-72Vdc. The maximum obtained energy efficiency of the converter is about 94%. According to the authors' knowledge, this is the maximum efficiency ever achieved in flyback converters switching in MHz frequency range. The results are very encouraging for the development of high frequency, high power density and low cost isolated power converters.

Published

2016

52. Power Converter and Control Design for High-Efficiency Electrolyte-Free Microinverters

Author

Gu, Bin, Electrical and Computer Engineering, Lai, Jih-Sheng, Meehan, Kathleen, Nelson, Douglas J., Centeno, Virgilio A., and Baumann, William T.

Subjects

Hybrid Transformer, Double line ripple, Microinverters, Power Converter, MPPT, MOSFET inverters, High-Efficiency, Electrolyte-Free

Abstract

Microinverter has become a new trend for photovoltaic (PV) grid-tie systems due to its advantages which include greater energy harvest, simplified system installation, enhanced safety, and flexible expansion. Since an individual microinverter system is typically attached to the back of a PV module, it is desirable that it has a long lifespan that can match PV modules, which routinely warrant 25 years of operation. In order to increase the life expectancy and improve the long-term reliability, electrolytic capacitors must be avoided in microinverters because they have been identified as an unreliable component. One solution to avoid electrolytic capacitors in microinverters is using a two-stage architecture, where the high voltage direct current (DC) bus can work as a double line ripple buffer. For two-stage electrolyte-free microinverters, a high boost ratio dc-dc converter is required to increase the low PV module voltage to a high DC bus voltage required to run the inverter at the second stage. New high boost ratio dc-dc converter topologies using the hybrid transformer concept are presented in this dissertation. The proposed converters have improved magnetic and device utilization. Combine these features with the converter's reduced switching losses which results in a low cost, simple structure system with high efficiency. Using the California Energy Commission (CEC) efficiency standards a 250 W prototype was tested achieving an overall system efficiency of 97.3%. The power inversion stage of electrolyte-free microinverters requires a high efficiency grid-tie inverter. A transformerless inverter topology with low electro-magnetic interference (EMI) and leakage current is presented. It has the ability to use modern superjunction MOSFETs in conjunction with zero-reverse-recovery silicon carbide (SiC) diodes to achieve ultrahigh efficiency. The performance of the topology was experimentally verified with a tested CEC efficiency of 98.6%. Due to the relatively low energy density of film capacitors compared to electrolytic counterparts, less capacitance is used on the DC bus in order to lower the cost and reduce the volume of electrolyte-free microinverters. The reduced capacitance leads to high double line ripple voltage oscillation on DC bus. If the double line oscillation propagates back into the PV module, the maximum power point tracking (MPPT) performance would be compromised. A control method which prevents the double line oscillation from going to the PV modules, thus improving the MPPT performance was proposed. Finally, a control technique using a single microcontroller with low sampling frequency was presented to effectively eliminate electrolyte capacitors in two-stage microinverters without any added penalties. The effectiveness of this control technique was validated both by simulation and experimental results. Ph. D.

Published

2014

53. Distribution Transformer Voltage Control Using a Single-Phase Matrix Converter

Author

Rui Wang, Henk Huisman, Korneel Wijnands, Power Electronics Lab, Electromechanics and Power Electronics, EIRES System Integration, Electrical Energy Systems, and Power Conversion

Subjects

AC-AC converter, On-load tap changer (OLTC), Hybrid transformer, AC-AC converter, Single-phase matrix converter, Single-phase matrix converter, Hybrid transformer, On-load tap changer(OLTC)

Abstract

A new topology is proposed for fully-electronic tap changers in distribution transformers. In every single phase, the voltage is regulated by a 2x1 matrix converter, which can be extended using the concept of multilevel converters. The topology allows reaching the desired functionality with one single tap, which reduces the cost of the transformer.