Description
The losses in a bridge rectifier can easily become significant when
low voltages are being rectified. The voltage drop across the bridge is a
good 1.5 V, which is a hefty 25% with an input voltage of 6V. The loss
can be reduced by around 50% by using Schottky diodes, but it would
naturally be even nicer to reduce it to practically zero. That’s
possible with a synchronous rectifier. What that means is using an
active switching system instead of a ‘passive’ bridge rectifier.
The principle is simple: whenever the instantaneous value of the
input AC voltage is greater than the rectified output voltage, a MOSFET
is switched on to allow current to flow from the input to the output. As
we want to have a full-wave rectifier, we need four FETs instead of
four diodes, just as in a bridge rectifier. R1–R4 form a voltage divider
for the rectified voltage, and R5–R8 do the same for the AC input
voltage. As soon as the input voltage is a bit higher than the rectified
voltage, IC1d switches on MOSFET T3.
Just as in a normal bridge rectifier, the MOSFET diagonally opposite
T3 must also be switched on at the same time. That’s taken care of by
IC1b. The polarity of the AC voltage is reversed during the next
half-wave, so IC1c and IC1a switch on T4 and T1, respectively. As you
can see, the voltage dividers are not fully symmetrical. The input
voltage is reduced slightly to cause a slight delay in switching on the
FETs. That is better than switching them on too soon, which would
increase the losses.
Circuit diagram:
Be sure to use 1% resistors for the dividers, or (if you can get
them) even 0.1% resistors. The control circuit around the TL084 is
powered from the rectified voltage, so an auxiliary supply is not
necessary. Naturally, that raises the question of how that can work. At
the beginning, there won’t be any voltage, so the rectifier won’t work
and there never will be any voltage... Fortunately, we have a bit of
luck here. Due to their internal structures, all FETs have internal
diodes, which are shown in dashed outline here for clarity.
They allow the circuit to start up (with losses). There’s not much
that has to be said about the choice of FETs – it’s not critical. You
can use whatever you can put your hands on, but bear in mind that the
loss depends on the internal resistance. Nowadays, a value of 20 to 50
mW is quite common. Such FETs can handle currents on the order of 50 A.
That sounds like a lot, but an average current of 5 A can easily result
in peak currents of 50 A in the FETs.
The IRFZ48N (55 V @ 64 A, 16 mW) specified by the author is no longer
made, but you might still be able to buy it, or you can use a different
type. For instance, the IRF4905 can handle 55 V @ 74 A and has an
internal resistance of 20 mR. At voltages above 6 V, it is recommended
to increase the value of the 8.2-kR resistors, for example to 15 kR for
9V or 22 kR for 12 V.
Author: Wolfgang Schubert, Elektor Electronics Magazine
Source http://www.extremecircuits.net/2010/05/power-mosfet-bridge-rectifier.html
Source http://www.extremecircuits.net/2010/05/power-mosfet-bridge-rectifier.html
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