Accurate Power Loss Model Derivation of a High-Current Dual Active Bridge Converter for an Automotive Application

An accurate power loss model for a high-efficiency dual active bridge converter, which provides a bidirectional electrical interface between a 12-V battery and a high-voltage (HV) dc bus in a fuel cell car, is derived. The nominal power is 2 kW, the HV dc bus varies between 240 and 450 V, and the battery voltage range is between 11 and 16 V. Consequently, battery currents of up to 200 A occur at nominal power. In automotive applications, high converter efficiency and high power densities are required. Thus, it is necessary to accurately predict the dissipated power for each power component in order to identify and to properly design the heavily loaded parts of the converter. In combination with measured efficiency values, it is shown that conventional converter analysis predicts substantially inaccurate efficiencies for the given converter. This paper describes the main reasons why the conventional method fails and documents the different steps required to predict the power losses more accurately. With the presented converter prototype, an efficiency of more than 92% is achieved at an output power of 2 kW in a wide input/output voltage range.

[1]  D.M. Divan,et al.  A three-phase soft-switched high power density DC/DC converter for high power applications , 1988, Conference Record of the 1988 IEEE Industry Applications Society Annual Meeting.

[2]  I. A. Khan DC-to-DC converters for electric and hybrid vehicles , 1994, Proceedings of 1994 IEEE Workshop on Power Electronics in Transportation.

[3]  Johann W. Kolar,et al.  Performance Optimization of a High Current Dual Active Bridge with a Wide Operating Voltage Range , 2006 .

[4]  Douglas J. Nelson,et al.  Energy Management Power Converters in Hybrid Electric and Fuel Cell Vehicles , 2007, Proceedings of the IEEE.

[5]  R. D. De Doncker,et al.  Calculation of losses in ferro- and ferrimagnetic materials based on the modified Steinmetz equation , 1999, Conference Record of the 1999 IEEE Industry Applications Conference. Thirty-Forth IAS Annual Meeting (Cat. No.99CH36370).

[6]  M. Jovanovic,et al.  A new family of full-bridge ZVS converters , 2004, IEEE Transactions on Power Electronics.

[7]  Alberto Tenconi,et al.  Temperatures Evaluation in an Integrated Motor Drive for Traction Applications , 2006, IEEE Transactions on Industrial Electronics.

[8]  J.W. Kolar,et al.  A novel low-loss modulation strategy for high-power bi-directional buck+boost converters , 2007, 2007 7th Internatonal Conference on Power Electronics.

[9]  Charles R. Sullivan Optimal choice for number of strands in a litz-wire transformer winding , 1997 .

[10]  L. Zhu,et al.  A novel soft-commutating isolated boost full-bridge ZVS-PWM DC-DC converter for bidirectional high power applications , 2004, 2004 IEEE 35th Annual Power Electronics Specialists Conference (IEEE Cat. No.04CH37551).

[11]  Ho-Gi Kim,et al.  Fault Diagnosis of a ZVS DC–DC Converter Based on DC-Link Current Pulse Shapes , 2008, IEEE Transactions on Industrial Electronics.

[12]  Huafeng Xiao,et al.  A ZVS Bidirectional DC–DC Converter With Phase-Shift Plus PWM Control Scheme , 2007, IEEE Transactions on Power Electronics.

[13]  A. Isurin,et al.  Achieving a wide input voltage and output power load range step-down DC-DC conversion with good full range efficiency at 4kW , 2006, Twenty-First Annual IEEE Applied Power Electronics Conference and Exposition, 2006. APEC '06..

[14]  Concettina Buccella,et al.  A Coupled Electrothermal Model for Planar Transformer Temperature Distribution Computation , 2008, IEEE Transactions on Industrial Electronics.

[15]  Srdjan M. Lukic,et al.  Energy Storage Systems for Automotive Applications , 2008, IEEE Transactions on Industrial Electronics.

[16]  Jumar Luís Russi,et al.  Coupled-Filter-Inductor Soft-Switching Techniques: Principles and Topologies , 2008, IEEE Transactions on Industrial Electronics.

[17]  H. Akagi,et al.  A Bidirectional Isolated DC–DC Converter as a Core Circuit of the Next-Generation Medium-Voltage Power Conversion System , 2007, IEEE Transactions on Power Electronics.

[18]  A. Khaligh,et al.  Power electronics intensive solutions for advanced electric, hybrid electric, and fuel cell vehicular power systems , 2006, IEEE Transactions on Power Electronics.

[19]  Sung-Sae Lee,et al.  Full ZVS-Range Transient Current Buildup Half-Bridge Converter With Different ZVS Operations to Load Variation , 2008, IEEE Transactions on Industrial Electronics.

[20]  Kaushik Rajashekara,et al.  Power Electronics and Motor Drives in Electric, Hybrid Electric, and Plug-In Hybrid Electric Vehicles , 2008, IEEE Transactions on Industrial Electronics.

[21]  O. Garcia,et al.  Bi-directional DC/DC Converter for Hybrid Vehicles , 2005, 2005 IEEE 36th Power Electronics Specialists Conference.

[22]  Hua Bai,et al.  Eliminate Reactive Power and Increase System Efficiency of Isolated Bidirectional Dual-Active-Bridge DC–DC Converters Using Novel Dual-Phase-Shift Control , 2008, IEEE Transactions on Power Electronics.

[23]  Yan-Fei Liu,et al.  A Practical Transformer Core Loss Measurement Scheme for High-Frequency Power Converter , 2008, IEEE Transactions on Industrial Electronics.

[24]  Loganathan Umanand,et al.  Multiphase Bidirectional Flyback Converter Topology for Hybrid Electric Vehicles , 2009, IEEE Transactions on Industrial Electronics.

[25]  L. Zhu,et al.  A Novel Soft-Commutating Isolated Boost Full-Bridge ZVS-PWM DC–DC Converter for Bidirectional High Power Applications , 2006, IEEE Transactions on Power Electronics.