Electric power conversion systems – Current conversion – Including d.c.-a.c.-d.c. converter
Reexamination Certificate
2002-04-09
2003-05-13
Toatley, Jr., Gregory J. (Department: 2838)
Electric power conversion systems
Current conversion
Including d.c.-a.c.-d.c. converter
C363S127000, C363S080000, C363S089000
Reexamination Certificate
active
06563719
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates to DC-DC converters and, more particularly, to a self-driven, synchronous rectification scheme for a DC-DC power converter.
There is an ever-increasing demand in the power electronics market for low voltage and high current DC-DC converters. As output voltage is desired to be 3.3V or lower, even a state-of-the-art schottky diode with a forward voltage drop of 0.3V has an unacceptable amount of power loss.
Because of this, synchronous rectifier circuits are often used to improve the efficiency of DC-DC converters. Generally, there are two types of synchronous rectifier circuits, self-driven and externally driven. Since the self-driven mode is usually less complex, less costly and more reliable, it is preferred for use with most low voltage DC-DC converter applications.
FIG.
1
(A) illustrates a conventional self-driven synchronous rectification, asymmetrical, zero voltage switching (ZVS) half-bridge (HB) topology which is only generally suitable for applications where the output voltage is in the range of from about 3.3V to 6V. Referring to
FIG. 1B
, the gate-drive voltages V
gs3
and V
gs4
of synchronous rectifiers (SRs) S
3
and S
4
, respectively, are as follows: (1)
V
gs3
=
2
N
s
N
p
D
V
in
=
2
N
D
V
in
=
V
o
1
-
D
(
t
0
≤
t
≤
t
1
)
(
1
)
V
gs4
=
2
N
s
N
p
(
1
-
D
)
V
i
n
=
2
(
1
-
D
)
N
V
i
n
=
V
o
D
(
t
1
≤
t
≤
t
2
)
(
2
)
wherein, V
in
is the input voltage; V
o
is the output voltage; D is the steady-state duty cycle; N
p
is the number of primary winding turns of the transformer; N
s
is the number of secondary turns of the transformer; and N is the turn ratio of the transformer. The turn ratio of the transformer TR is calculated by dividing the number of primary windings by the number of secondary windings (i.e. N=N
p
/N
s
).
FIG.
1
(B) illustrates the switching waveform occurring in the converter illustrated in FIG.
1
(A). As shown in FIG.
1
(B), the gate-drive voltage V
gs4
of S
4
is always higher than the gate-drive voltage V
gs3
of S
3
if D is less than 50%. If we assume that the minimum steady-state duty cycle D at heavy load is 30%, then V
gs3
is about 1.4V, and V
gs4
is about 3.3V. Since most synchronous rectifiers (including logic level devices) only work well with the gate-drive voltage between about 4V and 20V, the circuit shown in FIG.
1
(A) only works well when the output voltage V
0
is between 2.9V to 6V. If the output voltage is below 2.9V, S
3
would be under driven. If the output voltage were above 6V, then S
4
would be over driven. In either case the synchronous rectifiers are easily rendered inoperative.
FIG.
2
(A) shows a circuit diagram of an asymmetrical ZVS HB converter incorporating the self-driven synchronous rectifier circuit of the invention disclosed in U.S. patent application Ser. No. 09/932,398, filed Aug. 17, 2001, the entire disclosure of which is incorporated by reference herein. The self-driven synchronous rectifier circuit of FIG.
2
(A) includes two power switches S
1
and S
2
; a transformer Tr having a primary winding N
p
, a secondary winding N
s
and an auxiliary winding N
a
; two secondary synchronous rectifiers S
3
and S
4
; two diodes D
1
and D
2
; and two zener diodes ZD
1
and ZD
2
.
In the circuit of FIG.
2
(A), when S
3
conducts, the gate-drive voltage of S
4
is clamped by D
1
. Also, when S
4
conducts, the gate-drive voltage of S
3
is clamped by D
2
. In other words, D
1
and D
2
prevent S
3
and S
4
from conducting at the same time. ZD
1
and ZD
2
operate to restrain the gate over voltage of S
3
and S
4
, respectively. Because of this circuit configuration, the self-driven synchronous rectifier circuit operates normally at various output voltages, such as low output voltages of 2.9V or lower and/or high output voltages above 6V.
FIG.
2
(B) illustrates the switching waveform of the converter shown in FIG.
2
(A). V
gs1
and V
gs2
represent the gate voltage waveforms of the two power switches S
1
and S
2
. V
p
is the primary voltage waveform of transformer Tr. V
Na
is the voltage waveform of the auxiliary winding. V
gs3
and V
gs4
represent the gate voltage waveforms of the two synchronous rectifiers S
3
and S
4
. V
gs3
and V
gs4
are calculated as follows:
V
gs3
=
N
a
N
p
D
V
i
n
(
t
0
≤
t
≤
t
1
)
(
3
)
V
gs4
=
N
a
N
p
(
1
-
D
)
V
i
n
(
t
1
≤
t
≤
t
2
)
(
4
)
wherein, D is the on-time of switch S
1
in percent duty cycle; 1-D is the on-time of switch S
2
in percent duty cycle; N
p
is the number of primary winding turns of transformer Tr; N
a
is the number of auxiliary winding turns of the transformer Tr; and V
in
is the input voltage.
Comparing equations (3) and (4) above with equations (1) and (2), it can be seen, the gate voltage of self-driven synchronous rectifiers S
3
and S
4
may be adjusted by selecting the number of auxiliary winding turns N
a
of transformer Tr. This selection of the auxiliary number of winding turns N
a
ensures a reasonable gate-drive voltage for the synchronous rectifiers S
3
and S
4
even when the output voltage is lower than 2.9V or higher than 6V.
Conventionally, the demand for self-driven synchronous rectifier is satisfied by the second scheme. But as logic integrated circuits have migrated to lower working voltages, it is expected that the next generation of integrated circuits will require power supplies with voltage in the 1-2V range. This will confront the second self-driven scheme with great challenges. As shown in FIG.
2
(A), in practical application the circuit has a premise:
2N
s
≧N
a
(5)
A very low output voltage, namely 1.5V or less, would require a reduction in the number of turns of the winding N
s
. However, a reduction in the number of turns of the winding N
a
would not ensure a reasonable gate drive voltage for the synchronous rectifiers. On the other hand, if the number of turns of the winding N
a
are made substantially greater than the number of turns of the winding N
s
, i.e., if 2N
s
≦N
a
the winding N
a
will short through the loop of N
a
, D
1
, S
4
and ZD
1
(or the loop of N
a
, D
2
, 2N
s
, S
3
and ZD
2
). If this occurs, the self-driven circuit shown in FIG.
2
(A) will not work.
This invention discloses a novel self-driven scheme that overcomes the above-mentioned drawbacks of the prior art self-driven schemes.
SUMMARY OF THE INVENTION
A self-driven synchronous rectifier circuit in accordance with one aspect of the present invention includes an input circuit including a transformer having a primary winding for receiving a voltage, a secondary winding and an auxiliary winding. First and second synchronous rectifiers connected to the secondary winding of the transformer and responsive to the signal across the auxiliary winding are provided for selectively and alternatively turning the synchronous rectifiers ON and OFF. A first clamping circuit is provided for clamping the second synchronous rectifier when the first synchronous rectifier is turned ON and a second clamping circuit is provided for clamping the first synchronous rectifier when the second synchronous rectifier is turned ON. The first clamping circuit includes a first switching device operative to disable the first clamping circuit when the second clamping circuit is operative, and the second clamping circuit includes a second switching device operative to disable the second clamping circuit when the first clamping circuit is operative.
In accordance with another aspect, the self-driven synchronous rectification circuit of the present invention includes two power switches S
1
and S
2
; a transformer Tr having a primary winding N
p
, a secondary winding N
s
and an auxiliary winding N
a
; two secondary synchronous rectifiers S
3
and S
4
; two diodes D
1
and D
2
; and two zener diodes ZD
1
and ZD
2
; and t
Hua Guichao
Jiang Yi
Bel-Fuse Inc.
Laxton Gary L.
Ostrolenk Faber Gerb & Soffen, LLP
Toatley , Jr. Gregory J.
LandOfFree
Self-driven synchronous rectification scheme does not yet have a rating. At this time, there are no reviews or comments for this patent.
If you have personal experience with Self-driven synchronous rectification scheme, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Self-driven synchronous rectification scheme will most certainly appreciate the feedback.
Profile ID: LFUS-PAI-O-3081425