Electric power conversion systems – Current conversion – Including d.c.-a.c.-d.c. converter
Reexamination Certificate
2001-05-07
2003-04-08
Sherry, Michael (Department: 2838)
Electric power conversion systems
Current conversion
Including d.c.-a.c.-d.c. converter
C363S017000, C363S098000, C363S132000
Reexamination Certificate
active
06545883
ABSTRACT:
BACKGROUND OF INVENTION
1. Field of Invention
The present invention relates generally to power conversion and, more generally, to DC-DC switch-mode power converters.
2. Description of the Background
DC-to-DC power converters are power-processing circuits that convert an unregulated input DC voltage to a regulated DC output voltage. There are two basic methodologies for accomplishing regulated power conversion. The first is called “linear regulation” because the regulation characteristic is achieved with one or more semiconductor devices operating in the linear region. Linear regulators provide the advantages of simplicity, low output noise, fast response times, and excellent regulation. They may, however, be unacceptably inefficient in certain applications.
The second methodology is called “switch-mode” conversion, which, in contrast to linear regulation, offers the powerful advantage of high efficiency. In this case, the voltage conversion is achieved by switching one or more semiconductor devices rapidly between their “on” (or conducting) state and their “off” (or non-conducting) state such that the appropriate amount of energy is transferred to the load. This principle is called pulse width modulation (PWM).
Switch-mode DC-to-DC power converters typically include an inverter, a transformer having a primary winding coupled to the inverter, and a rectifier circuit coupled to a secondary winding of the transformer. The inverter typically includes an actively controlled semiconductor switch that converts the DC input voltage to an alternating voltage, which is magnetically coupled from the primary winding of the transformer to the secondary winding. The rectifier circuit rectifies the alternating voltage on the secondary winding to generate a desired DC output voltage. An output filter is also typically included to smooth the output voltage and/or current.
To achieve high efficiency and high performance power conversion, it is desirable to use low voltage rating switching devices for better switching and conduction characteristics. It is also desirable to employ converter circuits with relatively continuous power transfer to alleviate the need for heavy filtering for the output and/or input.
One known switch-mode converter is the single-ended forward converter with a passive reset circuit. Such a circuit topology, a resonant-reset forward converter, is illustrated in FIG.
1
. When the primary side power switch Q
1
is turned on, the input voltage V
in
is coupled to the secondary side of the converter through the transformer T
1
. The secondary side voltage is rectified to provide the DC output voltage V
out
. When the primary side power switch Q
1
is turned off, the magnetizing flux of the transformer T
1
is reset by the voltage appearing on the resonant capacitor Cr, and the output choke current free wheels through the rectifier D
2
. Typical waveforms for the input current I
in
and the rectified voltage V
rec
for the resonant-reset forward converter of
FIG. 1
are illustrated in FIG.
2
.
The major drawback of this type of converter is that the voltage stress on the semiconductor devices, such as the switch Q
1
, is very high. Thus, semiconductor switches with higher voltage ratings ordinarily have to be utilized. In addition, the resonant-reset forward converter is not very efficient with synchronous rectification, discussed later, especially for wide input voltage ranges and large load variations.
Another known switch-mode converter, the active-clamp forward converter, is illustrated in FIG.
3
. This type of converter includes a series-connected reset switch Q
2
and a resonant capacitor C
r
connected in parallel with a winding of the transformer T
1
, in this case the primary winding. The reset switch Q
2
and capacitor C
r
form a “reset circuit” that actively resets the transformer T
1
. Typical waveforms for the input current I
in
and the rectified voltage V
rec
for the active-clamp forward converter of
FIG. 3
are illustrated in FIG.
4
.
The active-clamp forward converter reduces the voltage stress on the active switching elements (such as the switches Q
1
and Q
2
), thereby permitting the usage of low voltage rating devices. However, as far as the input current I
in
and output voltage V
out
are concerned, both the resonant-reset forward converter and the active-clamp forward converter have pulsating input and output power as illustrated in
FIGS. 2 and 4
, respectively, which necessitate bulky filtering components.
Another known switch-mode converter, the forward-flyback converter, allows the transformer flux to operate under a dc bias condition and has a continuous rectified output voltage. Its input current, however, remains pulsating. It is also known to use a separate boost inductor with a half-bridge converter to achieve both smooth input current and output voltage. The boost inductor, however, is generally bulky in order to achieve the continuous-current mode operation.
Another aspect to achieve high efficiency for switch-mode converters has been the replacement of the conventional rectifier diodes in the rectifier circuit (such as the diodes D
1
and D
2
in the converters of
FIGS. 1 and 3
) with MOSFETs, which have extremely low conduction losses. The “self-driven” scheme of synchronous rectification, which uses the secondary winding voltage to drive the rectifier MOSFET directly or feed a gate driver circuit for the MOSFET, is known to be simple, effective, and cheap. In order to use such a self-driven mechanism, it is preferable that the winding voltage on the secondary side be well balanced in the whole operating range.
In view of the preceding, there exists a need in the art for a high efficiency and cost-effective switch-mode converter that uses low voltage stress semiconductor devices, provides smooth power transfer without bulky filters, and is able to use the effective self-drive technique for the rectifier MOSFETs.
BRIEF SUMMARY OF THE INVENTION
The present invention is directed to a DC-DC switch-mode power converter. According to one embodiment, the converter includes a transformer having first and second series-connected primary windings, a first capacitor connected in series to the second primary winding, a first switch for cyclically coupling an input voltage to the first and second primary windings, a second capacitor, and a second switch for cyclically coupling the first and second primary windings to the second capacitor. The converter may also include a rectifier circuit coupled to the transformer, wherein the rectifier circuit includes a pair of self-driven synchronous rectifiers.
According to another embodiment, the converter includes a boost converter, including the first primary winding of the transformer, the first and second switches which, when energized alternately, create a current in the first primary winding, and the second capacitor connected to the second switch. In addition to the boost converter, the converter also includes an asymmetrical half-bridge converter, including the second primary winding, the first and second capacitors, the first and second switches, a secondary winding of the transformer, and a secondary circuit coupled to the secondary winding. The secondary circuit may include a rectifier circuit including a pair of self-driven synchronous rectifiers.
Embodiments of the present invention provide many advantages and improved features relative to prior art switch-mode power converters. For instance, the present invention allows low voltage rating MOSFETs with improved switching and conduction characteristics to be utilized, thus providing enhanced efficiency. An additional feature of the present invention is that the output voltage is continuous. As a result, smaller output filter components may be utilized. A further feature of the present invention is that the input current has less ripple components without using an extra magnetic component; therefore, small input filter components may be utilized. Additionally, self-driven synchronous rectifiers may be used for the rectifier circuit of the pres
Martin William H.
Xing Kun
Artesyn Technologies, Inc.
Kirkpatrick & Lockhart LLP
Laxton Gary L.
Sherry Michael
LandOfFree
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