| Abstract |
Forward converter with active clamp is a suitable topology for a low output voltage and high output
current DC-DC power supply module. The topology can be used in a resonant transition manner to
obtain a low voltage over the main switch at turn-on instant. A low voltage, or even zero voltage, is
obtainable by adjusting the magnitude of the magnetizing current of the transformer and the delay
between the two primary side switches. An increased magnetizing current, however, increases
conduction losses in the primary side of the converter and may consume the advantage gained in the
switching losses. The converter can also be easily used for self-driven synchronous rectification.
However, the aim for low switching losses for the primary side switch may deteriorate performance
of the self-driven synchronous rectifiers, particularly at high loads. This paper presents a study of the
use of the resonant transition in Forward with active clamp and self-driven synchronous rectifiers.
The emphasis is on the comparison of the achieved efficiency with different voltage levels over the
primary switch prior to turning it on. Measurement results show that, at low loads, a reduced voltage
level improves the efficiency but, on the other hand, at high loads the advantage is not so significant,
or it may be totally lost, mainly due to the increased losses of the self-driven synchronous rectifiers.
The paper includes discussion on the effect of the magnetizing inductance on the efficiency of the
converter and the optimal voltage level at which the primary switch should be turned on.
Measurement results from a 3.4 V, 30 A prototype converter are included. |
