Your search keyword '"Badstuebner, Uwe"' showing total 3 results

1. Optimization of a 5-kW Telecom Phase-Shift DC–DC Converter With Magnetically Integrated Current Doubler.

Author

Badstuebner, Uwe, Biela, Juergen, Christen, Daniel, and Kolar, Johann W.

Subjects

*DC-to-DC converters, *MAGNETIC devices, *VOLTAGE doublers, *ELECTRIC current rectifiers, *DEGREES of freedom, *ELECTRIC switchgear, *SHOCK absorbers, *ELECTRIC inductors, DESIGN & construction

Abstract

The development of new converter systems with higher power density and/or efficiency offers many degrees of freedom for the design parameters as a large number of system component values have to be defined, where all of which are interdependent, to some extent, on another. Therefore, an automated optimization procedure, based on comprehensive analytical models and the resulting optimal design parameters, e.g., switching frequency or transformer design, to achieve the most compact and/or efficient design, is presented in this paper. In addition, the design of a volume-optimized 400/46–56-V phase-shift dc–dc converter with a current doubler rectifier and the underlying analytical models are also introduced. The power density of the converter is increased by integrating the output inductors in the transformer's core. A new lossless magnetic snubber circuit is introduced, which damps the intrinsic voltage ringing of the rectifier diodes and feeds the ringing energy to the output. The experimental results prove the analytical models and the design procedure. The 5-kW dc–dc converter prototype has a power density of 147 \W/in^3 (9 kW/L) and a maximum efficiency of 94.4% at 54-V output voltage and full load. [ABSTRACT FROM AUTHOR]

Published

2011

2. Design of a 5-kW, 1-U, 10-kW/dm³ Resonant DC--DC Converter for Telecom Applications.

Author

Biela, Juergen, Badstuebner, Uwe, and Kolar, Johann W.

Subjects

*CASCADE converters, *TELECOMMUNICATION systems, *ELECTRONIC circuits, *SEMICONDUCTORS, *MATHEMATICAL analysis, *PROTOTYPES

Abstract

The demand for decreasing cost and volume and also for increasing efficiency leads to a constantly increasing power density of converter systems. For maximizing the power density of a 5 kW telecom supply, an optimization procedure that automatically balances the switching frequency, semiconductor and passive losses, and thermal performance has been developed. This procedure and the belonging analytical converter and transformer models are presented in this paper. Moreover, the resulting optimized design, which has a power density of 10 kW/dm³ and an efficiency of 94.5% at a height of 1 U, is presented. [ABSTRACT FROM AUTHOR]

Published

2009

3. Impact of Power Density Maximization on Efficiency of DC—DC Converter Systems.

Author

Biela, Juergen, Badstuebner, Uwe, and Kolar, Johann W.

Subjects

*ELECTRIC current converters, *ELECTRIC charge, *DIRECT currents, *ELECTRIC circuits, *PARALLEL resonant circuits

Abstract

The demand for decreasing costs and volume leads to a constantly increasing power density of industrial converter systems. In order to improve the power density, further different aspects, like thermal management and electromagnetic effects, must be considered in conjunction with the electrical design. Therefore, a comprehensive optimization procedure based on analytical models for minimizing volume of dc-dc converter systems has been developed at the Power Electronic Systems Laboratory of the Swiss Federal Institute of Technology (ETH Zurich). Based on this procedure, three converter topologies-a phase-shift converter with current doubler and with capacitive output filter and a series-parallel resonant converter-are optimized with respect to power density for a telecom supply (400 V/48 V). There, the characteristic of the power density, the efficiency, and the volume distribution between the components as functions of frequency are discussed. For the operating points with maximal power density, the loss distribution is also presented. Furthermore, the sensitivity of the optimum with respect to junction temperature, cooling, and core material is investigated. The highest power density is achieved by the series-parallel resonant converter. For a 5-kW supply, a density of approximately 12 kW/L and a switching frequency of ca. 130 kHz are obtained. [ABSTRACT FROM AUTHOR]

Published

2009