Patent Grant
7915874
The non-isolated switching DC-to-DC converters can be broadly divided into three basic categories based on their input to output DC voltage conversion characteristics: a) step-down only (buck converter), step-up only (boost converter) and step-down/step-up such as flyback, SEPIC, and Ćuk converters (1,2). This invention relates to the step-down class of switching DC-to-DC power converters such as buck converter.
Many Point of Load Applications (POL) and Voltage Regulator Modules (VRM's) require a rather large step-down conversion ratios, such as 12:1 or even 24:1 to convert the standard 12V input voltage to 1V or 0.5V output regulated voltage required by the modern microprocessors and other electronic loads. This invention also relates to this particular subset of the step-down converters. However, it is equally applicable to a broader class of other moderate to high step-down voltage conversions.
Classifications of currently known switching converters can also be made based on the type of the voltage and current waveforms exhibited by the switches into three broad categories:
The present invention creates an entirely different new fourth category of the hybrid-switching converters consisting of a resonant inductor and a resonant capacitor forming a resonant circuit for a part of a switching period and a hybrid transformer obeying square-wave switching laws over the entire switching period while the resonant inductor is fully flux balanced during only one part of the switching cycle, either ON-time interval or OFF-time interval. This results in unique three-switch converter topologies as opposed to the two or four switch topologies, which are required in all prior-art converters of the three categories described above. Because of the mixed use of the square-wave switching and unique resonant inductor switching a term hybrid-switching method is proposed for this new switching power conversion method. The resonant capacitor takes a dual role, as it forms a resonant circuit during OFF-time interval with the resonant inductor, while during ON-time interval operates like a capacitive energy storage and transfer device such as, for example, in the Ćuk converter (1,2).
Another classification can be made with respect to number of switches used, such as two, four, six etc. The present Square-Wave Switching or Pulse Width Modulated (PWM) switched-mode power conversion theory (and their resonant modifications described above) a-priori excludes the converter topologies with the odd number of switches, such as 3 switches, 5 switches (5). The PWM switching method is based on the classical square-wave switching characterized by square-wave like current and voltage waveforms of its switches over the entire switching period. The direct consequence is that switches come in complementary pairs: when one switch is closed its complementary switch is open and vice versa. Thus when half of the switches are ON their complementary switches are OFF and vice versa for second OFF-time interval. Thus, the converters are characterized by two distinct switching intervals (ON-time interval and OFF-time interval) and even number of switches, such as 2, 4, 6, and cannot have an odd number of switches, such as 3, 5, etc.
The present invention breaks the new ground by introducing the switching converters featuring three switches, which results in hybrid switched-mode power conversion method and very high conversion efficiency.
The present invention also breaks another new ground by having a resonant inductor placed in series with the active switch in direct violation of the heretofore fundamental assumption that such connection is not permissible as leading to large voltage over-stresses on those switches (5).
The present invention also breaks anther new ground by using a hybrid transformer in a dual role of transferring inductive and capacitive energy storage through it. Present modifications of the buck converter such as tapped-inductor buck use tapped inductor but no separate resonant inductor.
The main objective is to provide an alternative to the present buck converter and tapped inductor buck converter to provide the converter with large step-down conversion ratios needed, such as 24:1 and achieve that with much improved efficiency while providing simultaneously magnetic size reductions and a fast transient response. This is achieved by providing step-down converter with a hybrid transformer, which in addition to inductive energy transfer of tapped-inductor buck converter, provides a simultaneous transfer of the resonant capacitor discharge current to the load via same two winding magnetic structure but now operating as a true ac transformer, hence the proposed name hybrid transformer. Both energy transfer mechanisms provide the increased total power to the load thereby increasing efficiency and simultaneously reducing the size and weight.
Although one of the main applications of the present invention is for the large step-down (12:1) and low output voltages such as 1V, the same advantages described are also applicable to other output voltages and moderate step-down conversion ratios such as 48V to 12V and 15V to 5V conversion.
The following notation is consistently used throughout this text in order to facilitate easier delineation between various quantities:
a illustrates a prior-art buck converter,
a shows input current of the buck converter in
a shows the prior-art tapped-inductor buck converter and
a shows the voltage waveform on the primary side of the tapped-inductor buck converter in
a illustrates the input current of the converter in
a shows a first embodiment of the present invention and
a illustrates an all MOSFET implementation for the three switches of the converter in
a illustrates a branch comprising a MOSFET transistor in series with an inductor, and
a illustrates a linear switched network for converter of
a illustrates one equivalent linear circuit model for linear switched network of
a illustrates simplified circuit model of
a shows the predicted half-wave sinusoidal resonant inductor current for the converter of
a illustrates a voltage waveform across the N turns of the hybrid transformer of the converter in
a shows the family of DC voltage gain characteristics for different hybrid transformer turns ratio's n in the converter of
a illustrates the load current of the converter in
a shows the hybrid transformer for the converter in
a shows the linear switched network for converter of
a illustrates converter circuit of
a illustrates the input and output current waveforms for the converter of
a illustrates the resonant capacitor, resonant inductor and hybrid transformer secondary currents for the converter of
a illustrates the input and output currents for the converter of
a illustrates the input and output currents for the converter of
a illustrates the input and output currents for the converter of
a illustrates a prior-art buck converter implemented with two controllable MOSFET transistors and
a illustrates the input and output current waveforms in the buck converter of
a illustrates the input and output current waveforms for converter in
a illustrates one embodiment of converter in
a illustrates one embodiment of converter in
a illustrates another embodiment of present invention,
a illustrates the converter circuit for OFF-time interval for the converter in
a illustrates a voltage waveform across N turns of hybrid transformer of the converter in
a shows the family of the DC voltage gain plots obtained for different hybrid transformer turns ratio's n for the converter of
a shows the converter circuit of
a shows the input and output current waveforms for the converter of
a illustrates converter circuit of
a illustrates the simplified schematic of the experimental prototype optimized for efficiency and
a shows the efficiency measurements for the converter of
a shows the efficiency measurements for the converter of
a shows the efficiency measurement for 12V to 1.3V, 30 A buck converter reported in (6) and
a shows the two-phase extension of the present invention in which two modules are operating at 50% duty ratio and in parallel but phase shifted for half a period in order to obtained the reduced output ripple voltage and
a shows the output current waveforms of the two modules in
The non-isolated prior-art Pulse Width Modulated (PWM) buck switching converter shown in
The minimum implementation of semiconductor switches in buck converter is shown on
V=DVg (1)
There are three fundamental problems associated with the buck converter when it is required to operate at a large step-down conversion ratios such as 12:1 and 24:1 as needed for modern microprocessors requiring 1V or 0.5V voltage from a 12V input source:
In order to solve the problem of the prior-art buck converter which must operate at 4% duty ratio to achieve the large 24:1 step-down conversion needed, a prior-art tapped-inductor buck converter of
The following definition of the tapped-inductor in
Turns N1 and N2 of the tapped-inductor and their dot connections are made with reference to their designations in
N=N1+N2 (2)
wherein N is an integer number for primary number of turns of the tapped-inductor and N2 is another integer number for number of turns of the secondary of the tapped-inductor. Note that this makes N2 turns common to both primary and secondary windings. Note also when switch S is turned-OFF there is no current in N1 turns and the inductive energy stored in the tapped-inductor magnetizing inductance during ON-time interval is released to the load during OFF-time interval.
In special applications requiring large step-down and low output voltage, the small size of tapped-inductor indicates that the secondary winding turns N2 can be reduced just to one turn:
N2=1 (3)
so that the two turns ratios can now be defined:
n=N/N2=N; (4)
We will use this turns ratio n as parameters in subsequent analysis and comparisons. However, the turns N1 and N2 will also be invoked at some instances, where the reference is needed to particular windings to refer to the current flowing through them or voltage across them.
The voltage waveform on the primary side of the tapped-inductor with N turns as defined in
VgDTS=Vn(1−D)TS (5)
M=V/Vg=D/(n−(n−1)D) (6)
where M is a DC voltage gain as a function of the duty ratio D and the turns ratio “n”. The family of the DC voltage gains for increasing values of integer value “n” from 1, 2, 3, 4 etc. is shown by graphs in
The tapped-inductor does provide an additional step-down in voltage conversion ratio from primary to secondary winding as per (6), but it also produces at a transition point an unwanted jump in instantaneous current during the transition form ON-time interval to OFF-time interval as seen in waveforms of the input current (
Finally, note how the turn's ratios greater than 2 contribute only a small incremental additional step-down conversion gain for duty ratios lower than 0.5 (
The present invention is shown in
m=N1/N2 (7)
which has an additional role of amplifying the capacitor resonant discharge current by this turns ratio and deliver it via transformer secondary turns N2 to the load during the OFF-time interval.
For low voltage applications an all n-channel MOSFET implementation shown in
The other two switches S1 and S2 will in comparison have much-reduced rms currents. Note also their desirable connection, so that as seen in
The switching topology of
Such a configuration with three switches is not possible in conventional square-wave PWM and conventional true resonant switching converters (1, 2, 5). However, here it is essential for its operation and is made possible by the new hybrid-switching method, which uses a unique combination of the square-wave switching and resonant switching.
The switching topology of
However, crucial to the understanding of the operation of the present invention of
Two Windings Coupled on the Common Magnetic Core
Although it appears that the two windings coupled on the common magnetic core could have one and only one interpretation, this is not the case as the following analysis of the presently known two winding magnetic structures are reviewed. This will also serve as the definition of the terms, which will be from here on used in describing the magnetic structure used in the present invention.
Transformer and Autotransformers in General
Faraday discovered in 1831 a principle of magnetic induction of two windings and was therefore also the inventor of the transformer used today commonly in utility AC line power transmission. The transformer, as discovered by Faraday, is a magnetic device, which does not store energy, except for the very small fraction of the input current (1% or less) circulating in transformer magnetizing inductance which is needed to establish the magnetic flux in the core and enable instantaneous transfer of the input ac power to output ac power. As there is no energy stored, the magnetic core coupling the two windings is made of high permeability magnetic material and has no air-gap thus resulting in high magnetizing inductance and low magnetizing current.
Such transformer is also capable via winding turns ratio to step-up or step-down the input ac voltage. It also provides a galvanic isolation between primary and secondary windings important for safety protection from the high voltage primary potential. An autotransformer connection can be used when galvanic isolation is not needed in which case the primary and secondary winding have one common terminal. The other terminal of the secondary winding is then provided as a tap on the primary winding. Note that we will for this case reserve the autotransformer name to indicate a magnetic structure with no energy storage.
Therefore, these true ac transformers and autotransformers operate with bi-directional magnetic flux and corresponding bi-directional magnetic flux density B as shown in
Transformers as Used in Switching Converters
Ćuk-type Transformer and Bridge-Type Transformers
In switching converters, the transformers with such bi-directional flux capabilities and BH loop also exist, such as the transformer in the Ćuk converter (single ended transformer) which is designated as new converter in the
Forward Converter Transformer Type
Another transformer utilized in the well known forward converter also has no DC bias and no stored energy but falls short of the above described ac transformer, as it utilizes only one half of the core flux capability as illustrated in
Flyback Transformer Type
Unfortunately, in switching converters, the magnetic structure used in the flyback converter is also commonly called a transformer, even though it does not meet the fundamental feature of the transformer of not storing the energy. To the contrary, this type of magnetic structure actually stores the inductive energy in the in magnetizing inductance of the transformer during ON-time interval and then releases the stored inductive energy during the subsequent OFF-time interval. Therefore, the magnetic core must have an air-gap to store that energy and prevent the saturation of the core flux due to the DC-bias of the core, as illustrated in
Tapped-Inductor Type
We have already seen this tapped-inductor structure in the tapped-inductor buck converter. The tapped-inductor, is in-fact, just a variant of the flyback “transformer” as it also stores all the inductive energy in the magnetizing inductance during ON-time interval and releases it to the load during the OFF-time interval with the only difference being that it lacks the isolation feature since part of the winding is common to both primary and secondary windings. Thus, tapped-inductor could also be designated as a flyback “autotransformer”, to signify the lack of isolation feature.
Coupled-Inductor Magnetic Structure
In some switching converters, such as Cuk converter for example (1), the separate inductors have identical AC voltage excitation, so that the inductors could be coupled on the common magnetic core (1) resulting in two switching converter variants: one with the separate inductors and another with coupled-inductors with either converters being operational but with coupled-inductors bringing additional performance benefits. Note, therefore, the key difference with tapped-inductor magnetic structure as used in switching converters. For example, the tapped-inductor buck converter of
In most current applications the coupled-inductor structure results in the DC storage of two separate inductors added together resulting in the need for a gapped core. However, it is also possible to find the coupled-inductor structures in which DC ampere turns excitations of the two inductors cancel after magnetic coupling resulting in no DC energy storage and hence in a true ac transformer-like structure with no air-gap needed for storage. Such a transformer despite the DC bias in each separate inductor could be described through coupled inductor equations modeling the ac transformer.
Hybrid Transformer
In the switching converters it is possible to have a two-winding magnetic structure such as the one in the converter of
a) Tapped-inductor energy transfer
b) AC transformer energy transfer
This is a consequence of the fact that the converter of
a) inductive energy storage is transferred from input to output via a tapped-inductor with N primary winding turns and N2 secondary winding turns (turns ratio n) resulting in the inductive energy storage and respective DC-bias as in a tapped-inductor buck converter.
b) capacitive energy discharge of the resonant capacitor Cr during the OFF-time interval and in a transformer-like manner amplifying the capacitor resonant discharge current to secondary of the hybrid transformer by a turns ratio m and delivering it to load. Note also the respective directions of the actual resonant currents in the primary winding (into the dot marked terminal) and secondary winding (out of the dot terminal) which results in the sum of ampere turns of the two windings being equal in magnitude but opposite in sign, hence in net zero ampere turns. This confirms no energy storage for this resonant current transfer through the hybrid transformer.
Clearly, this combined inductive and capacitive energy storage and transfer ultimately result in the energy storage of the hybrid transformer of
An alternative way to calculate the net DC bias is to observe that the primary winding N1 is DC blocked by resonant capacitor Cr whose charge balance demands that the net DC current flowing into N1 winding is zero, hence no DC bias is generated from the primary N1 winding. Thus, all the DC bias is coming from the secondary N2 turn winding and the respective total current in that winding during the OFF-time interval.
Because the two winding structure operates partly as a tapped-inductor (for inductive current flow) and partly as a transformer (for capacitive discharge resonant current) this two winding structure is designated as a hybrid transformer.
Combined Capacitive and Inductive Storage and Transfer
The converter of
The energy in previous ON-time interval is during this OFF-time interval being released to the load through two different charge transfer paths as described below.
By the principle of linear superposition, the equivalent circuit model for discharge interval of
a) Secondary current discharge into the load (
b) Resonant current flow inductor current ir direct discharge into the load (
From
From
This results in the first basic relationship of the present invention, that the output current i0 is the sum of the resonant inductor current ir and the hybrid transformer secondary current iS, which are designated in
i0=ir+iS (8)
Therefore, the load current is being supplied with the current during both parts of the switching interval, the ON-time interval and OFF-time interval. The conventional tapped-inductor buck converter supplies the load with the inductive energy storage and transfer only, since there is no capacitive energy storage and transfer. The present invention, on the other hand, supplies to the load an additional current based on the capacitive energy storage and transfer via hybrid transformer action. This results in a fundamentally much more effective power transfer based on combined inductive and capacitive energy storage and transfer working together and in synchronism during two switching subintervals.
The load current during the OFF-time interval TOFF (
a) Inductive energy discharge through secondary winding of hybrid transformer.
b) Resonant discharge current of the resonant capacitor amplified by transformer turns ratio m and delivered to the load via hybrid transformer secondary. Note that this part was missing in the tapped-inductor buck converter.
c) Direct contribution of the resonant inductor current to the load. Note that this part is also missing in the tapped-inductor buck converter.
We now analyze a series of equivalent circuit models in
a) Steady-state DC voltage Vr on the resonant capacitor Cr which will, in turn, lead to determination of the DC voltage gain M and
b) Provide explanation for a unique one-half cycle resonant current flow of the resonant capacitor and resonant inductor current ir.
From the circuit model in
∫VCrdt=Vr−2V=0 (9)
since the DC voltage across the resonant inductor voltage must be zero, as the resonant inductor cannot support any DC voltage across it and must be fully flux-balanced during this OFF-time interval. From (9) the summation of DC voltages around the loop in
C>>Cr (10)
Finally, the switches are replaced with ideal short circuits to result in the final simple series resonant circuit model of
Note that the series connection of the active switch S2 and current rectifier CR is left in the circuit model of
This key feature of the present invention is experimentally confirmed with the resonant current ir measurement displayed in
The switch turn-OFF losses are often the major switching losses, Thus, one of the desirable design constraints placed initially is to have the OFF-time interval TOFF equal to half-time resonant interval Trh, that is:
TOFF=Trh=TR/2 (11)
where Tr is the resonant period given by:
Tr=1/fr (12)
and fr is the resonant frequency. This will result in variable switching frequency of operation. However, we will show later that this condition can be relaxed as the switch S2 can, in fact, be turned OFF before or after that zero current switching instance t2 without unwanted consequences so that the simpler constant switching frequency and variable duty ratio D control of output voltage could also be implemented.
The New Hybrid-Switching Method
The new hybrid-switching method can now be explained with the reference to
Finally, the half-sinusoidal resonant inductor current ir is shown in
Note that the resonant capacitor Cr plays a dual role as the energy storage and energy transfer capacitor as in regular PWM square-wave converters, such as the Ćuk (1,2) and the SEPIC converters (2). However, here capacitor discharge interval is not liner but resonant. For example, during the ON-time interval the resonant capacitor Cr displays the characteristic linearly increasing ac ripple voltage as displayed in
Another characteristic of this hybrid-switching method not present in any other resonant methods is that despite the clear presence of the resonance, the usual dependence of the DC voltage gain M on resonant component values Lr and Cr as well as on the load current is completely absent and the conversion gain M is dependent on duty ratio D only. From the above it is obvious how in this new hybrid-switching conversion method both capacitive and inductive energy storage and transfers are taking place simultaneously in transferring power from the source to the load using both resonant current and square-wave current switching.
Note the marked difference with respect to the energy transfer in the conventional buck converter of
Evaluation of DC Voltage Gain
We now turn to evaluation of the DC voltage gain first. We assume a duty ratio control D of the main switch SI.
Flux Balance on Two Magnetic Components
First the flux balance on the resonant inductor Lr obtained previously for n=2 case can be now generalized for an arbitrary turns ratio n to:
∫VCrdt=Vr−nV=0 (13)
We then apply the second flux balance criteria, the flux balance on the winding N (equality of the shaded areas in
∫VgD−(n+1)VD=nV(1−D) (14)
M=D/(n+D) (15)
Note a remarkable result (15). Despite the presence of the resonance, owing to the hybrid-switching method described above, the DC voltage gain M is only a function of the duty ratio D and the hybrid transformer turns ratio n and is NOT a function of resonant component values nor the load current I. All other prior-art switching methods employing one or more resonant inductors resulted in the heavy dependence on the resonant component values as well as the DC load current. Therefore, the output voltage of the converter in
Up until now, the resonant converters were intrinsically tied to the control and regulation via changing switching frequency relative to the fixed resonant frequency (which spanned the entire switching cycle) so the conventional resonant converters were a-priori excluded from the regulation via PWM duty ratio control. The present invention actually confirms that PWM duty ratio control is not only possible but also advantageous in this new type of hybrid switching converters employing the resonant currents flowing only during a switching subinterval, such as ON-time interval and not during the entire switching interval as in conventional resonant converter.
Resonant Circuit Analysis
Resonance Equations for OFF-Time Interval
In
We now undertake to solve the pertinent resonance equations, which will describe analytically such time domain solutions. The derived analytical results could then be used to calculate the component values needed for optimum operation of the converter.
From the resonant circuit model of
Lrdir/dt=vr (16)
Crdvr/dt=−ir (17)
whose solutions are:
ir(t)=Im sin ωrt (18)
vr(t)=RNIm cos ωrt (18)
where RN is characteristic impedance, ωr is radial resonant frequency, fr resonant frequency and Tr resonant period given by:
RN=√Lr/Cr (20)
ωr=1/√LrCr (21)
Tr=1/fr=2π√LrCr (22)
Note the importance of the quantity Tr. From the equivalent circuit model in
Resonant Inductor Size
Note from the equivalent circuit model of
As seen from
Resonant Capacitor Size
Resonant capacitor size is also rather small and typically comparable to the size of the resonant inductor. This comes as a result of two facts:
The DC voltage gain M (15) can also be expressed in the following form:
M=D/n(1+D/n)≦D/n (23)
The conversion gain of Mi of a fully isolated transformer (not autotransformer) converter type would be expected to result in conversion gain Mi given by:
Mi=D/n (24)
Thus, the voltage gain M of the present invention with hybrid transformer and step-down ratio n results in higher step-down conversion ratio than could be expected of the isolated converter types, such as the conventional forward converter type for example, with conversion gain (24). This is clearly attributed to the presence of the capacitive energy transfer, hybrid resonant switching, and the resonant current contribution to the load as per (9).
The family of the DC voltage gains M with turns ratio n as a parameter are displayed in the graphs of
From the comparison of two families of curves it is also clear that the present invention provides for the same duty ratios the significantly larger step-down conversion ratios than tapped-inductor buck. For example, for D=0.5 and n=2 the tapped-inductor conversion ratio is 3 while for present invention conversion ratio is 5. At duty ratio D=2/3 and for n=2, the present invention results in four times reduction of the input voltage compared to two times reduction of the tapped-inductor buck, thus a factor of two higher reduction at the same duty ratio and for same turns ratio n=2. Hence 12V input would be reduced to quite low 3V output voltage with present invention while it would result in 6V output with tapped-inductor buck converter. This is clearly attributed to the presence of the capacitive energy transfer and resonance via the hybrid-switching method. Comparison with the ordinary buck converter leads to even larger reduction factor of 8/3=2.67 so 12V would result in 8V output voltage in ordinary buck converter operated at 2/3-duty ratio. Note that 8/3 higher conversion ratios over the buck converter is achieved by addition of only a single turn to make a two winding hybrid transformer compared to a single turn inductor in buck converter. The DC-bias of the buck converter with single turn is actually higher than the DC bias of the hybrid transformer.
Note also that the operation at higher duty ratios is desirable as it leads directly to the reduction of the ac flux and magnetic size reduction as per graph in
It is now also instructive to compare the operation of the two converter types having the same DC voltage gain at same DC operating duty ratio D point but using the appropriate turns ratios for each case. For example, the present invention with n=2 will result in 5:1 step-down conversion ratio while the tapped-inductor buck converter at duty ratio D=0.5 would need to operate with n=4 as seen at the intersection of the two curves displayed in
Additional disadvantages are also described here with respect to the comparison of the actual load currents in two cases displayed in
Finally, the tapped-inductor buck converter load current has a much larger step-up at the transition from ON-time to OFF-time interval as seen by comparison of the load currents in two cases displayed in
Reduction of Turn-OFF Losses of the Main Input Switch
As explained in introduction with reference to
Hybrid Transformer Charge Transfer
We now review the energy transfer from input to output through the hybrid transformer for the special case of n=2 and duty ratio D=0.5 as illustrated in
First shown in
IDC/I=Mn/D (25)
Where M is the DC voltage gain (reduction) and n is turns ratio. Thus, for example, for n=4 and D=0.5, DC gain is M=1/9 and (25) results in 8/9. Thus interesting result is obtained. Despite the large number of turns DC bias in the hybrid transformer of present invention is actually smaller than the DC bias IDC in the single inductor buck converter.
However, in the present invention, an additional capacitive energy transfer is taking place through the N1 to N2 hybrid transformer as shown in equivalent circuit model of
ir2=ir1=ir (26)
This result is illustrated by the current waveforms displayed in
Note how the load current i0 is equal to current rectifier CR current ICR that has the magnitude of 2ir before splitting in half having one half ir1 part flowing as resonant inductor Lr current and the other ir2 part flowing as the secondary current of the hybrid transformer to be reunited as 2ir flowing into the load again.
Thus, a completely new phenomenon not heretofore observed in other conventional converters is taking place. The hybrid transformer serves the normal function of the 2:1 voltage step-down (and respective 1:2 current step-up) for the inductive current flow operating as a tapped-inductor type of magnetic coupling, but serves in addition as an ac transformer from the primary N1 to secondary side N2 for resonant capacitor discharge current. This is clearly being amplified more when the turn's ratio m is larger than one. For example, for m=3 (n=4), the current amplification is three times from primary N1 to secondary N2 side. Adding also another resonant current directly going to the load, this results in 4 times effective resonant capacitor discharge current going into the load. Note also that the inductive energy transfer through the tapped-inductor, as described previously in
This charge transfer is illustrated in the characteristic current waveforms in
We can now complete the resonant design equations by finding the equation for the peak magnitude Im of the resonant current ir (t). The second waveform in
Im=(π/2)Ig/(1−D) (27)
The source current can be easily correlated to DC load current and above equation expressed in terms of DC load current I. This completes the resonant design equations.
Voltage Stresses of the Three Switches
From the derived DC currents in all branches one can also derive analytical expressions for the rms currents in various branches so that the conduction losses of the three switches could be calculated. What remains is to determine the voltage stresses of all three switches so that the proper rated switching devices could be selected. From the circuit diagram for OFF-time interval in
S1: VS1=Vg−V (28)
S2: VS2=Vg−V (29)
CR: VCR=(Vg−V)/n (30)
Both active switches have lower voltage stresses than the comparable buck converter. However, note in particular large voltage stress reduction for the rectifier switch CR that conducts most of the power for the large step-down. For example, for 12V to 1V conversion and n=4, the blocking voltage of the rectifier switch is VCR=11/4 V=2.75V. This is to be compared with the blocking voltage of 12V for comparable buck converter or a factor of 4.4 reductions in voltage stress of the switch, which processes by far the most of the power to the load for high step-down conversion and is critical for overall efficiency.
Experimental Verification
The experimental prototype was built to verify basic operation of the converter and to highlight the salient features of the key waveforms. The following were the operating conditions: Vg=24V, I=3 A, TOFF=20 μsec is constant with duty ratio D and switching frequency variable while turns ratio n was used as a variable parameter, since two hybrid transformers were used with n=2 and n=4 turns ratio.
In the first experiment 2:1 step-down hybrid transformer was implemented and the measured output voltage of 4.67V corresponds very closely to the predicted voltage of 4.8V at duty ratio D=0.5 since the theoretical step-down conversion ratio is 5. The input current and output current are shown in
The corresponding input and output current waveforms are shown in
a shows the salient features at 50% duty ratio of the remaining three key current waveforms: resonant capacitor current, resonant inductor current and the hybrid transformer secondary current. Note that the load current is the sum of the resonant inductor current and the hybrid transformer secondary current.
The measurements below were conducted with the hybrid transformer turns ratio changed to n=4. The much larger step-down conversion ratio of 9 to 1 at 50% duty ratio is confirmed as well as 17 to 1 at 0.25 duty ratio.
a illustrates at 50% duty ratio the input and output current waveforms, while
Finally the measurement was conducted to operate the converter at the boundary between the continuous and discontinuous conduction mode. However, since here all three switches are MOSFET transistors, the discontinuous inductor current mode is prevented as illustrated by the measurements below.
Comparison with the Buck Converter
It is interesting now to make the comparison of the buck converter with two switches and a single inductor shown in
Conduction Loss Comparison
a illustrates operation of the buck converter with 12V to 1V step-down conversion. Note a very small duty ratio measured to be 0.1 and a rather large inductive ripple current. Note also a large peak turn-OFF current of 4.25 A exceeding the load current of 3 A.
Note also the much-reduced peak turn-OFF current of 1 A when compared to higher than 4 A peak current of the buck converter. This will result in large reduction of the turn-OFF losses of at least four times.
It is now very instrumental to compare the measurements of the mean values and rms values of the input and output currents for two converters operating with the same 12 to 1 step down, that is converting 24V source voltage to 2V output voltage. The measurements should be interpreted relative to the DC load current of 3 A, so that the actual DC load current conditions could simply be scaled-up by the same ratio for any other load current in practical applications. Table I compares the input and output current measurement and Table II compares the switch rms current measurement.
Even though the buck converter has only two switches compared to the three switches of the present invention, the input switch in the buck converter, due to more than two times higher rms current, has loss comparable or higher than the two switches S1 and S2 in present invention. Although the synchronous rectifier switch in buck converter has a lower rms current, this is fully compensated by the fact that in the present invention this switch has a blocking voltage more than 4 times lower than the buck converter. Thus, substantial reduction of these dominant conduction losses could be achieved by use of lower rated voltage devices. Alternatively, for the same conduction losses, the synchronous rectifier switch in present invention could be implemented with a much smaller silicon area than the comparable switch in the buck converter as the silicon area reduction is proportional to square of reduced blocking voltage.
Size and Cost of Resonant Capacitor and Resonant Inductor
An argument could be made that the present invention uses an additional resonant capacitor and resonant inductor, which might impact the cost and size and cause additional sizable losses. However, a quick look at the typical practical applications with large step-down conversion such as 12V to 1V reveals that the resonant components are both negligible in terms of the size and their impact on losses. For example, the rms current of the above example is measured to be 0. A, which is 6 times lower than the DC load current. Hence for a 30 A typical load a 5 A resonant capacitor with 5 A rms ripple current rating is needed. This is easily met with two chip capacitors with 1210 package each with 3 A ripple current rating. The same applies to a resonant inductor that can be implemented in most application due to its 45 A DC current capability, 25 nH inductance, very small footprint and small profile. This is obviously made possible by the hybrid switching method in which resonant inductor is excited by the very small ripple voltage on the resonant capacitor resulting in 40 times or smaller size of the resoant inductor than the buck inductor.
Comparison of the Hybrid Transformer with the Buck Inductor
Finally we compare the size of the hybrid transformer and the buck inductor needed for the large step-down applications. First we compare this for the case of 2:1 turns ratio hybrid transformer, meaning that only one additional turn is used as compared to the single inductor buck made with one turn. Note that the buck converter must operate at 20% duty ratio to result in the same step-down conversion ratio of 5 to 1 that is achieved in the converter of
First note that the flux of both inductor and hybrid transformer are following the same graph of
Note also that the present invention has DC saturation current of the hybrid transformer substantially lower than the output DC current and therefore lower DC-bias than comparable single-turn buck inductor. For example, in the above case only the current flowing through the secondary one turn of the hybrid transformer effects the DC-bias of the hybrid transformer, since the N1 turns of the primary are charge balanced and do not add anything to DC-bias irrespective how many turns are used, such as 4, 6 or more. Only N2=1 turn effects overall DC-bias. For the above example, at 50% duty ratio, the average of the hybrid transformer secondary current over the whole switching interval TS a is IDC=½×3QTS=1.5QTS since the direct contribution of resonant inductor to the load does not count. Q is the charge stored in the resonant capacitor during the ON-time interval. However this current does count for the load current which can be evaluated over the whole interval as I=½QTS+½4QTS=2.5QTS. The net result is that I=2.5/1.5 IDC=1.7 IDC that is hybrid transformer DC-bias is approximately 1.7 times lower than the output DC load current. Thus, seemingly impossible result is obtained that the single turn inductor in the buck converter has actually 1.7 times higher DC-bias than hybrid transformer of the present invention regardless of how many turns N1 it uses.
Both 1.6 times lower AC flux and 1.7 times lower DC-bias of the hybrid transformer lead directly to combine factor of 2.72, which can be used to reduce the size of the hybrid transformer relative to the buck inductor size. Alternatively a much better strategy is to keep the same size and reduce the operating switching frequency by a factor of almost 3 times. Note that with the reduction of the frequency comes also the proportional reduction of the core losses, which make it possible to even further reduce the switching frequency and allow operation at higher flux density. Practical factor of 4 of reduction of switching frequency is feasible. Thus, the present invention can still operate at the 150 kHz switching range (and operating in optimum frequency range for chip capacitors), while the comparable buck converter would need to operate at 600 kHz or higher to result in the same size. Clearly previously discussed two times larger turn-OFF losses will now become 8 times larger due to operation at 4 times higher switching frequency.
The reduced DC-bias of the hybrid transformer as compared to a buck inductor should not come as a surprise due to the presence of the capacitive energy transfer, which is lacking in the buck converter. In fact the above comparison will become even more favorable for the present invention when the operation is made at duty ratio above 50% due to the increased capacitive energy transfer contribution to the load at higher duty ratios.
Other Switch Implementations
Hybrid transformer can be replaced by a transformer with two separate windings to result in two extensions illustrated in
Other switch implementations are possible using different semiconductor switch technologies. For example,
An alternative converter topology could be obtained by connecting the branch with second switch S2 and the resonant inductor of basic converter in
Yet another embodiments is obtained when the resonant inductor is connected to the ground as shown in
a) simple drive for S1 and S2 switches using the high-side driver and direct drive for synchronous rectifier switch S3.
b) protection of the load from switch S1 failing short and staying in short condition.
Those skilled in the art could also find other beneficial placements of the resonant inductor, which would also employ above combined inductive and capacitive energy storage and transfer which is the main feature of the present invention.
Protection of the Load
The converter extension of
In the buck converter, shorting of the main switch will cause that the input 12V voltage will be directly applied to low 1V output and result in damage to the expensive loads such as microprocessors.
This cannot happen in this extension of the present invention, since shorting of the input switch will not cause the damage to the load. After a small transient spike the output voltage will be reduced to near zero output voltage as the resonant capacitor and output capacitor serve as an effective capacitive divider. Since the output capacitor value is many times (at least ten times) higher in value than the resonant capacitor, the output voltage will be limited to 1/10 of input voltage or 1.2V.
Equally important, a single-point failure of the resonant capacitor (its shorting) will not result in the catastrophic destruction either as the present invention of
Modeling and Analysis
Equivalent circuit model analysis of converter in
Evaluation of DC Voltage Gain
We now turn to evaluation of the DC voltage gain for the converter topology in
Flux Balance on Two Magnetic Components
First the flux balance on the resonant inductor Lr can be now shown for an arbitrary turns ratio n to:
∫vrdt=Vr−(n−1)V=0 (31)
We than apply the second flux balance criteria, the flux balance on the hybrid transformer (equality of the shaded areas in
VgD−nVD=nV(1−D) (32)
M=D/n (33)
Note that the converter in
The family of the DC conversion gains as a function of duty ratio for different turns ratios n is shown in graphs in
Resonant Circuit Analysis
The same resonant circuit model is obtained for this case (
Hybrid Transformer Charge Transfer
We now review the energy transfer from input to output through the hybrid transformer for the special case of n=2 and duty ratio D=0.5 for the hybrid transformer of
First, the inductive energy storage and transfer trough the hybrid transformer did not change from the previous topology. The same inductive energy storage and transfer is also taking place in the tapped-inductor buck converter.
However, there is now a change in the capacitive energy transfer through the hybrid transformer as modeled by the equivalent circuit model of
ir2=ir1=ir=i0 (34)
This result is illustrated by the current waveforms displayed in
Note, however, that there is no resonant current ir1 contribution to the load, since this current is now NOT delivered to the load, but is instead circulating internally in the converter (actually sent to ground lead). As the result, the output current is equal to the current of the secondary of the hybrid transformer during OFF-time interval and not twice that value in previous case. Therefore, there is less current delivered to the load in this converter topology owing to the absence of the direct resonant current contribution to the load. Consequently, the DC voltage conversion ratio will always be higher in this case.
However, once again, a new phenomenon not heretofore observed in other conventional converters is taking place. The hybrid transformer serves the regular function of the voltage step-down (and respective current step-up) for the inductive current flow, but serves in addition as a resonant current amplifier with turn ratio m amplification from primary to secondary winding. Due to the absence of the direct resonant current flow to the load, this results in one time effective amplification of the primary hybrid transformer current as seen in waveforms for iS in
This charge transfer is illustrated in the characteristic current waveforms in
Experimental Comparison of Two DC Voltage Gains
We now compare the DC voltage gains of two topologies.
Voltage Stresses of the Three Switches
Let us now evaluate the voltage stresses in the converter of
S1: VS1=Vg (35)
S2: VS2=Vg (36)
S3: VS3=Vg/n (36)
Both active switches have voltage stresses equal to the input voltage as in a buck converter. However, note in particular large voltage stress reduction for the synchronous rectifier switch S3 that conducts most of the power for the large step-down. For example, for 12V to 1V conversion and n=4, the blocking voltage of the synchronous rectifier switch is VS3=12/4 V=3V. This is to be compared with the blocking voltage of 12V for comparable buck converter or a factor of 4 times reduction in voltage stress of the switch.
Voltage Regulation Via Duty Ratio Control
The converters of present invention in
a) they contain one separate resonant inductor which is fully fluxed balanced during OFF-time interval and its value together with the resonant capacitor value is used to determine the optimum turn-OFF-time interval.
b) they contain a hybrid transformer which provides the transfer of both inductive and capacitive input energy storage to the output. This hybrid transformer is flux balanced over the entire switching period.
c) the first two features result in unorthodox switching converter topology consisting of three switches only.
d) has the DC voltage gain dependent on the duty ratio only despite the half-wave sinusoidal resonant current present in the converter which is essential for its operation.
All other converters based on resonance have a DC voltage gain not only dependent on the resonant component values, but also of not being suitable for the duty ratio control. In these resonant converters the output voltage is controlled in a resonant circuit fashion by changing the ratio of switching frequency to the resonant frequency, which is not capable to regulate the output voltage over even the modest change in DC load currents due to high dependence on the resonance Q factor. However, the present invention employs the very simple duty ratio control of the output voltage and is independent on the load current and resonant component values.
The optimal control method introduced so far is constant OFF-time, variable ON-time control which ultimately means also a variable switching frequency. However, for the practical step-down conversion ratios, such as 4:1 and higher as used in experimental examples, the change of the ON-time interval is relatively small from the nominal value, so that even though a variable switching frequency is employed, the change of switching frequency is also small. However, if so desired, a constant switching frequency and variable duty ratio could be employed at the minor sacrifice in efficiency due to presence of zero coasting intervals and somewhat increased values of rms currents.
Experimental Verification of Efficiency
Prototype of a 48V to 1V and 1.5V Converter with 35 A Load
To demonstrate ultra high efficiency, the step-down converter with hybrid transformer and a resonant inductor was built with the power stage shown in schematics of
Specifications: 48V to 1.5V, 52 W converter and 48V to 1V, 35 W converter
Components:
MOSFETS transistors:
S1=IRFH5006; 60V; 4.1 mΩ
S2=IRFH5006
S3=3×IRFH55250; 25V; 1.2 mΩ
Input capacitor: 8×10 μF
Output capacitor: 12×47 μg
Resonant capacitor: 3×2.2 μF
Resonant inductor: 2 μH (RM4 core)
Hybrid transformer: 9:1 turns ratio Ls: 0.65 μH (core cross-section 52 mm2)
Resonant and switching frequency: 50 kHz
Graph of the efficiency and power loss as a function of the load current are shown in
Prototype of a 12V to 1.5V and 1V Converter with 35 A Load
To verify ultra high efficiency of the converter for standard 12V input voltage and low output voltages, the step-down converter with hybrid transformer and a resonant inductor was built with the power stage shown in schematics of
Specifications: 12V to 1.5V, 52 W converter and 12V to 1V, 35 W converter
Components:
MOSFETS transistors:
S1=IRFH55250; 25V; 1.2 mΩ
S2=3×IRFH55250; 25V; 1.2 mΩ
S3=IRFH55250
Input capacitor: 8×10 μF
Output capacitor: 12×47 μg
Resonant capacitor: 3×2.2 μF
Resonant inductor: 1.2 μH (RM4 core)
Hybrid transformer: 5:1 turns ratio Ls: 0.65 μH (core cross-section 52 mm2)
Resonant and switching frequency: 50 kHz
Graph of the efficiency and power loss as a function of the load current are shown in FIG. 40a and
Efficiency Measurement of the Buck Converter
It is now instructive to compare the obtained efficiency results on breadboard prototype of the present invention with the recently published data for the buck converter (6), which are repeated here and displayed in graphs of efficiency in
Two-Phase Extension
The common method to reduce the output voltage ripple in the buck converter is to use a multi-phase buck converter with several buck converters (typically four phases) are operated in parallel but phase shifted by a quarter of period to result in reduced ripple current and reduced output ripple voltage.
The same method could be also implemented to the present invention which shows two modules operated in parallel but shifted in phase for a half a switching period as illustrated in the Two-Phase Extension of
A three-switch step-down converter with a resonant inductor, a resonant capacitor and a hybrid transformer provides efficiency, size, cost and other performance advantages over the conventional buck converter and tapped-inductor buck converter.
Unlike buck converter and tapped-inductor buck converters, which use only inductive energy transfer, the present invention employs the capacitive energy transfer in addition to inductive energy transfer. The hybrid transformer performs the double duty simultaneously: transfers the input inductive energy storage to the load through a taped-inductor turns ratio n but also serves as a hybrid transformer to transfer the resonant capacitor discharge current to the load during OFF-time interval amplified by hybrid transformer turns ratio m.
Despite the presence of the resonant inductor current during the OFF-time interval, the output voltage is neither dependent on resonant component values nor on the load current as in conventional resonant converters but dependent on duty ratio D and hybrid transformer turn ratio n. Hence a simple regulation of output voltage is achieved using duty ratio control only.
The dual inductive and capacitive energy storage and transfer together with lower voltage stresses on the switches results in increased efficiency and reduced size and cost compared to buck converter and tapped-inductor buck converters.
The present invention also introduces a new hybrid switching method, which implements for the first time a use of odd number of switches, such as three in this case, which is strictly excluded from use in conventional Square-wave, Resonant and Quasi-resonant switching converters, which all require an even number of switches (2, 4, 6 etc.), operating as complementary pairs.
| Number | Name | Date | Kind |
|---|---|---|---|
| 6486642 | Qian | Nov 2002 | B1 |
| 6525513 | Zhao | Feb 2003 | B1 |
| 7215101 | Chang | May 2007 | B2 |
