Soft-switched DC-DC converters for PHEV charger
An efficient power conditioning system plays a significant role in the design of battery charging systems for plug-in hybrid electric vehicles (PHEVs). A typical PHEV battery charging system consists of two stages. The first stage is an ac-dc conversion stage which regulates the input power facto...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/72670 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | An efficient power conditioning system plays a significant role in the design of
battery charging systems for plug-in hybrid electric vehicles (PHEVs). A typical
PHEV battery charging system consists of two stages. The first stage is an ac-dc
conversion stage which regulates the input power factor, input current total
harmonic distortion and intermediate dc bus voltage. The second stage is a dc-dc
conversion stage which regulates the output voltage and provides galvanic isolation
between utility grid and PHEV battery pack. The research works presented in this
thesis focus on the dc-dc conversion stage of a PHEV charger.
The phase-shift modulated (PSM) isolated full-bridge (FB) dc-dc converter
topology is commonly preferred for the dc-dc stage. High efficiency, high power
density, high reliability, and galvanic isolation are the main features of this
topology. However, zero-voltage switching (ZVS) is not ensured for all switches at
light-load conditions resulting in poor efficiency of the converter. Furthermore,
high voltage spikes are present across output rectifier diodes due to voltage ringing
on the secondary side. These voltage spikes are further intensified with the increase
in series inductance or leakage inductance of the transformer, output filter
inductance and switching frequency. In addition, the voltage spikes increase the
electromagnetic interference (EMI) of the converter. Therefore, the motivation for
the research work presented in this thesis is to address these drawbacks in order to
obtain an improved performance for the dc-dc converter over the entire operating
range.
Auxiliary circuits can be added to the FB converter for improving the ZVS range.
Additionally, snubber circuits can minimize the voltage spikes. In this research
work, two new gating techniques, namely asymmetrical pulse-width modulation
(APWM) and trailing-edge pulse-width modulation (TEPWM) gating techniques
and a passive auxiliary circuit assisted topology are proposed to improve the
performance of the dc-dc conversion stage in a PHEV charger.
APWM/TEPWM gating techniques minimize the auxiliary inductance value by a
factor close to 2 compared to PSM for zero-voltage and zero-current switching
(ZVZCS) FB dc-dc converter with auxiliary inductor at both legs. An adaptive
frequency control, namely asymmetrical duty cycle frequency control (ADFC)
method is also proposed to further reduce the auxiliary inductance and improve the
efficiency for the same converter.
Another research work presented in this thesis comprising a FB dc-dc converter
with inductive and capacitive output filter topologies assisted by an auxiliary
transformer and auxiliary inductor is proposed. The proposed converter topologies
achieve ZVS for all switches over the entire battery charging range. The proposed
converter topology with inductive output filter is employed with a diode clamping
network on the primary side to minimize voltage spikes across output rectifier
diodes. The proposed converter topology with capacitive output filter is operated as
a current-driven rectifier to eliminate voltage spikes. These converter topologies
can achieve higher efficiency with the proposed APWM technique compared to the
conventional PSM technique.
In this thesis, the operation and steady-state analysis of each proposed converter
topology are explained in detail. The design considerations for the circuit
parameters are also given. The improved performance of the proposed gating
techniques and converter topologies is validated with experimental results obtained
from 100 kHz, 1.2 kW converter hardware prototypes. |
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