This invention relates to DC-to-DC converters and, in particular, to methods, systems, apparatus and devices for high-density, high-frequency, and high efficiency isolated dc-dc converters.
There are three conventional rectifier topologies for low voltage applications.
For the center-tapped rectifier, the transformer utilization is bi-directional, however, a single output filter inductor is used to carry the whole load current. The conventional center-tapped rectifier is shown in
a shows a current doubler rectifier and the corresponding key steady-state operation waveforms are shown in
In high-performance microprocessor and telecommunication applications, the system operation speed and integration density keeps increasing so that the required converter supply voltage continuously decreases while supply current continuously increases due to the increasing power level requirement. Since real estate on printed circuit boards is limited, high-current high-power-density power conversion is demanded for microprocessor and telecommunication applications. In general, conversion efficiency and thermal management are the restrictions against high power density.
High switching frequency is an effective way to improve power density, and topologies featuring high efficiency at high switching frequency are desirable. In addition, topologies with even current and thermal stresses are also demanded, especially for low voltage and high current applications. Because secondary-side conduction loss dominates the overall power loss in isolated low-voltage high-current dc-dc converters, secondary-side topologies are desirable to have low conduction loss and well-distributed power dissipation to improve overall conversion efficiency and satisfy thermal management requirement.
The present invention provides current tripler rectification topology for high current applications. Basically, an additional inductor is added in the current doubler rectifier to help share the load current, and each inductor carries only one-third of the load current. As a result, it has better power dissipation than the conventional center-tapped and current doubler topologies, leading to better thermal management and potentially improved power density. In addition, compared to center-tapped rectifier, transformer secondary winding utilization is also improved and the transformer winding conduction loss is reduced.
A primary objective of the invention is to provide new methods, systems, apparatus and devices for a current tripler secondary-side rectification topology for use in isolated dc-dc converters in high current applications.
A secondary objective of the invention is to provide new methods, systems, apparatus and devices for a current tripler secondary-side rectification for use in various primary topologies such as full bridge, half bridge and push pull topologies.
A third objective of the invention is to provide new methods, systems, apparatus and devices for a current tripler secondary-side rectification that has good thermal management, simplified magnetic design and low copper loss for inductor and transformer due to the fact that the load current is better distributed in three inductors.
A forth objective of the present invention is to provide new methods, systems, apparatus and devices for a current tripler secondary-side rectification that has high current capability; the rectification topology of the present invention has simple driving for synchronous rectifier application without increasing the complexity of the control and operation of primary-side topologies.
A fifth objective of the present invention is to provide new methods, systems, apparatus and devices for a current quadrupler rectification topology.
A sixth objective of the present invention is to provide new methods, systems, apparatus and devices for a current N-trupler rectifier topology.
A seventh objective of the present invention is to provide new methods, systems, apparatus and devices for secondary-side rectification topology in isolated converters.
The present invention provides a DC-to-DC converter having a transformer with a primary side winding and a secondary side winding having a tap, at first and second output filter inductor serially connected in parallel with the secondary winding, a center output filter inductor having a first end and a second end, the first end connected to the secondary tap and second end connected to a serial connection of the first and second output inductor, a serially connected first and a second switching device connected in parallel with the first and second output inductors for receiving a driving signal to control the operation of the first and second switching devices during steady state operation and a output load connected between the serial connection of the first and second output inductor and the serial connection of the first and second switching devices, wherein the output filter inductors evenly share an output current resulting in a reduction in current and thermal stress for high current application. The input stage applying ac voltage to the primary side winding of the transformer is a double-ended primary-side topology, such as a half bridge primary topology, a full bridge primary topology and a push-pull primary topology.
In a first embodiment, the transformer secondary winding is a center-tapped secondary winding and the transformer has a turns ration is n: 1:1 and the center output filter inductance includes a third output filter inductor forming a current tripler rectification topology, wherein the current tripler rectifier control and operation of the primary side topologies is the same as used for conventional center-tapped and current doubler rectifiers.
In a second embodiment, the transformed secondary side winding has a first and a second tap, the first tap between a first and second secondary winding and the second tap between the second secondary winding and a third secondary winding and the center output filter inductors include a fourth output filter inductor connected between the first tap and the serial connection of the first and second output filter inductors and a fifth output filter inductor connected between the second tap and the serial connection of the first and second output filter inductors forming a current quadrupler rectifier, wherein the first, second, fourth and fifth output filter inductors evenly share a load current and the transformer secondary side winding carries partial load current to have higher current capability for DC-DC conversion.
Another embodiment of the present invention provides a current N-tupler, wherein the transformer includes N-1 secondary-side windings having N-2 secondary taps between adjacent secondary side windings and the center output filter inductor includes N output filter inductors, one end of each output filter inductors connected to one of the (N-2) secondary side taps, the other end of the N output filter inductors connected to the serial connection of the first and second output filter inductors to form the N-tupler rectifier, wherein each of the N output filter inductors evenly shares 1/N load current.
Further objects and advantages of this invention will be apparent from the following detailed description of preferred embodiments which are illustrated schematically in the accompanying drawings.
a is a schematic diagram of a prior art forward rectifier (half-wave rectifier).
b shows waveforms corresponding to steady state operation of the forward rectifier shown in
a is a schematic diagram of a prior art center-tapped rectifier.
b shows waveforms corresponding to steady state operation of the center-tapped rectifier shown in
a is a schematic diagram of a prior art current doubler rectifier.
b shows waveforms corresponding to steady state operation of the current doubler rectifier shown in
a is a schematic diagram of a current tripler rectifier of the present invention.
b shows waveforms corresponding to steady state operation of the current tripler rectifier shown in
a is schematic diagrams showing operation of the current tripler rectifier during a first mode of operation, respectively, according to the present invention.
b is schematic diagrams showing operation of the current tripler rectifier during a second mode of operation, respectively, according to the present invention.
c is schematic diagrams showing operation of the current tripler rectifier during a third mode of operation, respectively, according to the present invention.
d is schematic diagrams showing operation of the current tripler rectifier during a fourth mode of operation, respectively, according to the present invention.
Before explaining the disclosed embodiments of the present invention in detail it is to be understood that the invention is not limited in its application to the details of the particular arrangements shown since the invention is capable of other embodiments. Also, the terminology used herein is for the purpose of description and not of limitation.
The method, system, apparatus and device of the present invention provides a current tripler rectification (CTR) topology and the key steady-state operation waveforms are shown in
Ignoring the leakage inductance and applying ac voltage pulse to the primary side of the transformer Tx as shown in
where Vin is the input voltage, and D is the steady-state duty cycle value. The dc voltage gain of the above current tripler rectifier is the same for both the center-tapped and the current doubler rectification topologies. By removing either the inductor L3, or by removing both the inductors L1 and L2 from the topology of the present invention, these respective conventional topologies are obtained.
Neglecting the inductor current ripple, each inductor's dc current is one third of the load current:
where Io is the load current. When the applied ac pulse is absolutely symmetrical, the dc bias of the transformer's magnetizing current is zero:
IM=0 (3)
The operation principle of the current tripler rectifier is described by four operation modes as shown in
In
and in the inductor L1 current L3 linearly increases as shown in
where Vo is the output voltage and n is the transformer's turns ratio. The inductor L3 is linearly charged by voltage difference between the reflected input voltage in the secondary side and the output voltage, and inductor current i3 is increasing with the slope:
During the Mode 1 interval shown in
Referring to
showing that each of the three inductor currents during Mode 2 are approximately one-third of the output current Io/3.
c shows an operational circuit during Mode 3 (t2<t<t3). As shown in
The inductor L2 is charged by the difference voltage
and the inductor current i3 linearly increases at the slope:
The inductor L3 is linearly charged by difference voltage
and i3 increases with the slope:
The operational circuit for Mode 4 is shown in
The operation mode returns to Mode 1 after Mode 4, and a next switch cycle starts.
The current tripler rectification topology of the present invention can be used with double-ended primary-side topologies such as push-pull, half bridge and full bridge. There is no difference between the current tripler rectifier and the conventional center-tapped and current doubler rectifiers in terms of the control and operation of the primary-side topologies. In addition, the driving signals for the secondary-side synchronous rectifiers (SRs) are identical to those for the conventional center-tapped and current doubler rectifiers.
In the topology of the present invention described above, there are three output inductors L1, L2 and L3 evenly sharing the load current Io and thus the current stress is relieved in high current applications. As a result, the inductors design is simplified and better thermal management is achieved.
Detailed comparison between the topology of the present invention and the conventional center-tapped and current-doubler rectifiers are shown in the table of
The inductor currents in the current tripler rectifier are only one-third of that in the center-tapped rectifier, while the individual inductor currents in the current doubler rectifier are half of that in the center-tapped rectifier. However, to achieve the same output ripple current, the filter inductance in the current doubler rectifier need to be doubled, and the filter inductance in the current tripler rectifier need to be tripled as shown in
Since the load current is evenly shared by three independent output inductors as shown in
Besides, the current tripler rectifier has better transformer utilization and lower transformer winding conduction loss than the center-tapped rectification in that the secondary winding in the rectifier is used all over the switch cycle and only carries partial load current when conducting. As shown in
Also, the addition of the third inductor is a benefit to PCB layout design and power density improvement. Since the physical size of the magnetic core is proportional to the energy stored in it
the total volume of three inductors should be the same as that of the current doubler rectifier and the center-tapped rectifier. For discrete magnetics approach, the individual inductor size is reduced, which makes PCB layout design more flexible. Further converter size reduction can benefit from integrated magnetics and correspondingly increase the power density.
Therefore, compared to the center-tapped rectifier and the current doubler rectifier, the current tripler topology of the present invention has high current capability, well-distributed power dissipation and good thermal management for high current applications.
The current tripler rectification concept of the present invention can be extended to the Current Quadrupler rectifier topology as shown in
In general, the current tripler rectification concept can be extended to the current N-tupler rectifier as shown in
load current, leading to more evenly distributed power dissipation over the power train and thus easier power management. As a matter of fact, current doubler and current tripler rectifiers are particular examples of the current N-tupler topologies where N is two and three, respectively.
Similar to the current tripler rectifier, the inductor magnetic design is simplified due to the reduction of the dc bias current and it has the same control and operation of primary side topology as conventional current doubler rectifier without any complexity increase in driving circuitry for switches SRs. However, the current N-tupler rectifier becomes impractical for higher current output when N is larger than four because there are too many filter inductors and secondary-side windings for the transformer resulting in complicated transformer structure as shown in
An experimental prototype of the symmetrical half bridge dc-dc converter with the current tripler rectifier was built with the nominal input voltage 48V, output voltage 1.2V, and maximum load current of 45 A. In the prototype, Si7456 is used for two main switches S1 and S2 of the primary-side half bridge converter, and Si7868 MOSFET manufactured by Vishay is used for the secondary-side synchronous rectifier SR1 and SR2, two in parallel each side. Core ER14.5/3F3 Manufactured by Bobbin is selected as the planar transformer with turns ratio of 12:1:1. The converter runs at the switching frequency of 211 kHz and each output inductor has an inductance value of 0.8 μH and DCR value of 0.588 mΩ.
The experimental current waveforms i1, i2 and i3 of the topology of the present invention are shown in
While the invention has been described, disclosed, illustrated and shown in various terms of certain embodiments or modifications which it has presumed in practice, the scope of the invention is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved especially as they fall within the breadth and scope of the claims here appended.
This application claims the benefit of priority to U.S. Provisional Patent Application No. 60/808,612 filed on May 26, 2006.
Number | Name | Date | Kind |
---|---|---|---|
4581690 | Russell | Apr 1986 | A |
5321596 | Hurst | Jun 1994 | A |
5353212 | Loftus, Jr. | Oct 1994 | A |
5539630 | Pietkiewicz et al. | Jul 1996 | A |
5541828 | Rozman | Jul 1996 | A |
5808879 | Liu et al. | Sep 1998 | A |
5877945 | Liu | Mar 1999 | A |
5936853 | Mweene | Aug 1999 | A |
6445599 | Nguyen | Sep 2002 | B1 |
6549436 | Sun | Apr 2003 | B1 |
6590791 | Zhou et al. | Jul 2003 | B1 |
6822882 | Jacobs et al. | Nov 2004 | B1 |
6836414 | Batarseh et al. | Dec 2004 | B1 |
6882548 | Jacobs et al. | Apr 2005 | B1 |
6906931 | Batarseh et al. | Jun 2005 | B1 |
6954367 | Yang et al. | Oct 2005 | B2 |
6980447 | Schaible et al. | Dec 2005 | B1 |
6982887 | Batarseh et al. | Jan 2006 | B2 |
7009849 | Ramabhadran et al. | Mar 2006 | B2 |
7049712 | Ying et al. | May 2006 | B2 |
7196916 | Batarseh et al. | Mar 2007 | B2 |
7342811 | Domb et al. | Mar 2008 | B2 |
Number | Date | Country | |
---|---|---|---|
60808612 | May 2006 | US |