KR101759619B1 - Power supply apparatus including the dc to dc convertor and power supply method thereof - Google Patents

Abstract

DC power supplies including DC converters are disclosed. The present invention relates to a DC voltage source for generating a DC voltage, a transformer having one primary winding and a plurality of secondary windings, a primary switch for alternately applying a DC voltage to both ends of the primary winding in response to a plurality of PWM signals, A plurality of rectifying and smoothing circuits for rectifying and smoothing the voltage induced in the corresponding secondary winding of each of the plurality of secondary windings, A secondary side switching unit for transmitting the output of the rectifying smoothing circuit to the load and for coupling the outputs of the rectifying smoothing circuits adjacent to each other among the plurality of rectifying smoothing circuits, And a digital control signal applied to vary the voltage level of the output voltage In response, a secondary-side switch control unit that outputs a plurality of switch control signals.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply apparatus including a DC-DC converter,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply apparatus including a DC-DC converter and a power supply method thereof, and more particularly, to a power supply apparatus including a DC-DC converter using a parallel- DC converter for efficiently supplying a voltage to a secondary winding of a transformer by using one pulse width modulation circuit at the time of power supply and a power supply method thereof.

The power supply to the electronic device is essentially used. BACKGROUND ART [0002] In various fields of industry, a variety of voltage supply devices for processing and applying a voltage to be supplied to an electronic device have appeared.

A DC-DC converter (DC-DC converter) may be included in such an electronic device.

Generally, a DC-DC converter (DC-DC converter) is a device that converts a DC power input from the outside into a predetermined DC power required by a load. Representative topologies of DC-DC converters include full bridge converters, push-pull converters, and half-bridge converters.

In recent years, power supply conversion circuits have been constructed through DC-DC converters in the field of power supplies where the output current must be high as the consumption current of the defense electronics continuously increases. Typically, in the case of guided weapons, the current required is very high due to the use of a servo motor and many sensors. In the case of a searcher such as a radar, the current required for amplifying the transmission output is very large. Therefore, as the system is miniaturized and the required current is increased, the necessity of such a power supply change circuit is continuously increased.

Meanwhile, as a method for realizing a DC-DC converter having a high step-up ratio, there is a method of configuring the outputs of the converters in series or in parallel using a plurality of DC-DC converters.

Generally, a high-voltage power supply for a navigator used in guided weapons should supply a voltage lower or higher than the reference voltage depending on the mode when power is supplied to the load, and the voltage fluctuation range is 2 to 3 times, It is necessary to change to a branch or three voltage.

As described above, the DC-DC converter used in the high-voltage power supply for the explorer has a range of voltage fluctuation of 2 to 3 times. Therefore, when a plurality of different DC-DC converters are used, , And when using a single DC-DC converter, there is a limitation of the output voltage range and low efficiency in a wide output range.

1 is a configuration diagram of a power supply device including two conventional DC-DC converters.

Referring to FIG. 1, in a power supply apparatus including a DC-DC converter to which the present invention is applied, two DC-DC converters 100 and 150 are connected in parallel, and two DC- DC converters 100 and 150 selectively operate.

Specifically, when a low voltage is required to be supplied to the load 120 in comparison with a predetermined voltage, the first DC-DC converter 100 is operated. When a high voltage is to be supplied to the load 120, -DC converter 150 is operated.

The operation of the first DC-DC converter 100 and the second DC-DC converter 150 will be described with reference to FIG. 1. In the first DC-DC converter 100, the first switch 102 and the second switch 104 Are respectively disposed between the DC voltage source 106 and the first transformer 110 at different ends of the primary winding to switch the voltage to be applied to the primary winding from the DC voltage source 106. [

At this time, the first switch 102 and the second switch 104 are turned on / off by the switching pulses A and B (138 and 140) generated in the first switch control unit 130, Voltages can be alternately applied in opposite directions to each other on the primary winding in accordance with the pre-charged duty ratio. The first transformer 110 of the first DC-DC converter 100 includes a primary winding and a secondary winding that generates a voltage induced by the voltage applied to the primary winding, and the secondary winding has a diode 112 And a smoothing rectifier circuit including a capacitor 114 and an inductor 116 and a capacitor 118. The voltage induced in the secondary winding is smoothed and smoothed by the smoothing rectifier circuit to be applied to the load 120 do.

The switching pulses A and B (138 and 140) for the operation of the first switch 102 and the second switch 104 of the first DC-DC converter 100 are outputted from the first switch control unit 130 .

The feedback circuit 132 of the first switch control unit 130 compares the voltage applied to the load 120 with a predetermined first feedback voltage and outputs a control signal for feedback control of the voltage to be applied to the load 120. [ To the PWM control unit 134. [ Where the control signal may be a signal corresponding to a voltage difference between the voltage applied to the load 120 and the first feedback voltage. The PWM control unit 134 outputs a PWM control signal for turning on / off the first switch 102 and the second switch 104 to the PWM generating unit 136. The PWM generator 136 generates a switching pulse A 138 and a switching pulse B 140 for turning on / off the first switch 102 and the second switch 104 in response to the PWM control signal To the first switch (102) and the second switch (104).

The third switch 152 and the fourth switch 154 in the second DC-DC converter 150 are located between the other end of the primary winding of the second transformer 160 and the DC voltage source 106, And switches the voltage to be applied to the primary winding of the second transformer 160. [

At this time, the third switch 152 and the fourth switch 154 are turned on by the switching pulses C, D (188, 190) generated in the second switch control unit 180 to apply the primary winding voltage of the DC voltage source 156 Can be turned on / off. The second transformer 160 of the second DC-DC converter 150 includes a primary winding and a secondary winding that generates a voltage induced by the voltage applied to the primary winding, and the secondary winding has a diode 162 A smoothing rectifier circuit including a rectifier rectifier circuit 164, an inductor 166 and a capacitor 168 is connected and connected and the voltage induced in the secondary side winding of the second transformer 160 by the smoothing rectifier circuit is rectified And smoothed and applied to the load 120.

The switching pulses C and D (188 and 190) for the operation of the first switch 152 and the second switch 154 of the second DC-DC converter 150 are outputted from the second switch control unit 180 .

The feedback circuit 182 of the second switch control unit 180 compares the voltage applied to the load 120 with a predetermined second feedback voltage to generate a control signal for feedback control of the voltage to be applied to the load 150. [ To the PWM control unit 184. Since the second feedback voltage is a configuration for the second DC-DC converter 150 to apply a higher voltage to the load 120 than the first DC-DC converter 100, the second feedback voltage is set to have a higher voltage level than the first feedback voltage. Respectively. The second PWM controller 184 outputs a PWM control signal for turning on / off the third switch 152 and the fourth switch 154 to the PWM generator 186. The PWM generator 186 receiving the PWM control signal generates a switching pulse C 188 and a switching pulse D 190 for turning on and off the third switch 152 and the fourth switch 154 To the third switch (152) and the fourth switch (154).

1, a plurality of DC-DC converters are required according to the number of output voltages, and additional control circuits are required to implement the DC-DC converters, thereby increasing the weight, volume, and price of the power supply there is a problem.

In order to solve the above problems, there is a need for a power supply device and a power supply method including a DC-DC converter capable of minimizing the complexity of a circuit even if the number of output voltages is increased.

Korean Patent Publication No. 10-2013-0039510 (published on April 22, 2013)

It is an object of the present invention to provide a power supply apparatus including a DC-DC converter for constituting a DC-DC converter in parallel and generating a plurality of output stages through switch control, Supply method.

According to an aspect of the present invention, there is provided a power supply device including a DC-DC converter, including: a DC voltage source generating a DC voltage; A transformer having one primary winding and a plurality of secondary windings; A primary side switch unit for alternately applying the DC voltage to both ends of the primary side winding in response to a plurality of PWM signals; A plurality of rectifying smoothing circuits for rectifying and smoothing a voltage induced in a corresponding secondary winding of each of the plurality of secondary windings; A secondary side switch for transferring a voltage applied from each of the plurality of rectifying smoothing circuits to a load in response to a plurality of switch control signals or a combination of outputs of rectifying smoothing circuits adjacent to each other among the plurality of rectifying smoothing circuits, part; A primary side switch control unit for comparing the voltage level of the output voltage delivered to the load with a preset feedback voltage to output the plurality of PWM signals; And a secondary switch controller for outputting a plurality of switch control signals in response to a digital control signal applied to vary the voltage level of the output voltage; .

Wherein the secondary side switch portion is connected between a corresponding one of the plurality of rectifying smoothing circuits and the load, and responsive to a corresponding one of the plurality of switch control signals, A plurality of voltage output switches for transmitting a voltage to the load; And an output terminal of a rectifying smoothing circuit disposed adjacent to the rectifying smoothing circuit among the plurality of rectifying smoothing circuits, wherein, in response to a corresponding switch control signal among the plurality of switch control signals, At least one circuit-linking switch for coupling in series; And a control unit.

Wherein the secondary switch control unit receives a digital control signal for adjusting a voltage level of the output voltage to be applied to the load and outputs an analog signal corresponding to the digital control signal; And a controller for receiving the analog signal output from the digital potentiometer and converting the analog signal to a digital signal to control the plurality of voltage output switches and the at least one circuit- An analog-to-digital converter for outputting a plurality of switch control signals; And a control unit.

Wherein the primary side switch unit is connected between the other end of the DC voltage source and the one end of the primary winding connected at one end between the two main winding wires of the primary winding, A first switching unit for applying a DC voltage to one end of the primary winding; And a control unit connected between the other end of the DC voltage source and the other end of the primary winding, and responsive to a second PWM signal of the plurality of PWM signals, alternating with the first switching unit, A second switching unit for applying the second switching signal to the second switching unit; And a control unit.

Wherein the primary side switch control unit comprises: an output voltage measuring unit for measuring a voltage level of the output voltage applied to the load; A feedback voltage generator for generating a feedback voltage for feedback control of a voltage level of the output voltage; A PWM controller for comparing the voltage measured by the output voltage measuring unit with the voltage of the feedback voltage and generating a control signal corresponding to the comparison result; And a PWM generator for varying a duty ratio of the first PWM signal and the second PWM signal in response to the control signal and outputting the duty ratio; And a control unit.

Each of the plurality of rectifying smoothing circuits being connected to both ends of a corresponding secondary winding of the plurality of secondary windings and rectifying the AC voltage induced in the secondary winding to a direct current; A smoothing unit for smoothing the voltage rectified by the rectifying unit and outputting the smoothed voltage; And a control unit.

The smoothing unit includes two diodes each having one end connected to both ends of the secondary winding. The smoothing unit includes an inductor having one end connected to the other end of the two diodes, and two inductors connected to the other end of the inductor and two And a capacitor connected in parallel with the inductor between the auxiliary windings.

The output voltage can be output at a very wide variety of voltage levels through simple control at any time without having the number of DC-DC converters corresponding to the required number of voltage levels according to the above-described embodiment of the present invention. Further, as the conventional structure of the feedback control circuit and the pulse width control signal generating circuit becomes simpler, the number of parts becomes smaller, and accordingly, the size and weight of the DC-DC converter can be reduced.

1 is a configuration diagram of a power supply device including two conventional DC-DC converters.
2 is a block diagram of a power supply apparatus including a DC-DC converter according to an embodiment of the present invention.
3 shows an example of an output voltage of a power supply apparatus including a DC-DC converter according to an embodiment of the present invention.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the preferred embodiments of the present invention with reference to the accompanying drawings. However, the present invention can be implemented in various different forms, and is not limited to the embodiments described. In order to clearly describe the present invention, parts that are not related to the description are omitted, and the same reference numerals in the drawings denote the same members.

Throughout the specification, when an element is referred to as "including" an element, it does not exclude other elements unless specifically stated to the contrary. The terms "part", "unit", "module", "block", and the like described in the specification mean units for processing at least one function or operation, And a combination of software.

2 is a block diagram of a power supply apparatus including a DC-DC converter according to an embodiment of the present invention.

Referring to FIG. 2, the DC-DC converter of the present invention includes a transformer 208 having one primary winding and a plurality of secondary windings, an input coupled to the primary winding of the transformer 208, And an output unit connected to the secondary windings of the plurality of secondary windings to apply an output voltage Vo to the load 236. Here, the plurality of secondary side windings are parallel connection structures to the primary side windings, and generate inductive power respectively in response to the voltage applied to the primary side windings. In FIG. 2, it is assumed that there are two secondary windings. However, the number of secondary windings can be variously adjusted.

And the primary side winding and the plurality of secondary side windings have two windings having different current transmission paths in accordance with the path for carrying the current. That is, the primary winding has two main windings 210 and 212, and a plurality of secondary windings that generate an inductive power by the voltage applied to the primary winding are respectively connected to two auxiliary windings 214 and 216 ), (218, 220). Hereinafter, the two main winding wires 210 and 212 will be referred to as first main winding wire 210 and the second main winding wire 212 respectively and the two auxiliary windings 214 and 216 of the secondary winding will be referred to as first The auxiliary windings 214 and the second auxiliary windings 216 and the two auxiliary windings 218 and 220 of the secondary windings are referred to as a third auxiliary winding 218 and a fourth auxiliary winding 218 .

The input unit includes a DC voltage source 206 for generating a DC voltage and a primary side switching unit. The primary side switching unit includes a first switching unit 202 and a second switching unit 204 for switching the DC voltage of the DC voltage source 206 to the primary side winding.

One end of the first switching unit 202 is connected to the other end of the first main winding line 210 and the other end of the first switching unit 202 is connected to a negative terminal of the DC voltage source. Is connected to the other end of the second main winding line (212), and the other end is connected to the negative (-) pole of the DC voltage source. The positive polarity of the DC voltage source 206 is connected to one end of the first main winding line 210 and one end of the second main winding line 212.

The output section includes a plurality of smoothing circuits corresponding to each of the plurality of secondary windings, a secondary switch section 240, a primary switch control section 250, and a secondary switch control section 270.

The voltages induced and generated in the plurality of auxiliary coils 214, 216, 218 and 220 of the secondary side winding are respectively rectified and smoothed through corresponding rectifying and smoothing circuits of the plurality of rectifying and smoothing circuits and output to the load 236 .

Specifically, the first rectifying and smoothing circuit rectifies and smoothes the voltage generated in the first auxiliary winding 214 and the second auxiliary winding 216 to convert the first output voltage V _O1 to the load 236 Output. 2, the first rectifying and smoothing circuit includes a first diode 222, a second diode 224, a first inductor 230 and a first capacitor 234, The cathode of the first diode 222 is commonly connected to one end of the first inductor 230 and the cathode of the second diode 224, One end of the first inductor 230 is connected to the positive pole of the first capacitor 234 and the anode of the second diode 224 is connected to one end of the second auxiliary winding 216, The other end of the first auxiliary winding 214 and the other end of the second auxiliary winding 216 are connected to the negative (-) pole of the first capacitor 234.

The second rectifying and smoothing circuit rectifies and smoothes the voltage generated in the third auxiliary winding 218 and the fourth auxiliary winding 220 and outputs the second output voltage V _O2 to the load 236.

Specifically, the second rectifying smoothing circuit includes a third diode 226, a fourth diode 228, a second inductor 232 and a second capacitor 235, and the anode of the third diode 226, The cathode of the third diode 226 is commonly connected to one end of the second inductor 232 and the cathode of the fourth diode 228, The other end of the second inductor 232 is connected to the positive pole of the second capacitor 235 and the anode of the fourth diode 228 is connected to one end of the second auxiliary winding 220 And the other end of the first auxiliary winding 218 and the other end of the fourth auxiliary winding 220 are connected to a negative (-) pole of the second capacitor 235.

2, the secondary side switching unit 240 includes a fourth switching unit 244 for performing switching for outputting the first output voltage V _O1 output from the first rectifying smoothing circuit to the load 236, And a fifth switching unit 246 for performing switching for outputting the second output voltage V _O2 output from the second rectifying smoothing circuit to the load 236. The secondary side switch unit 240 connects the first capacitor 234 of the first rectifying and smoothing circuit in series with the second capacitor 235 of the second rectifying smoothing circuit and supplies the load 236 And a third switching unit 242 for controlling the sum voltage of the first output voltage V _O1 and the second output voltage V _O2 to be applied.

The fourth switching unit 244 and the fifth switching unit 246 may be a voltage output switch for transmitting the voltage output from the corresponding rectifying and smoothing circuit to the load 236. The third switching unit 242, May be a smoothing circuit linking switch for coupling the outputs of the rectifying smoothing circuits adjacent to each other.

The third switching unit 242 is connected to the negative terminal of the first capacitor 234 and the positive terminal of the second capacitor 235 and the other terminal of the second inductor 232, And has the other end connected in common. The fourth switching unit 244 has one end connected to the negative (-) pole of the first capacitor 234 and the other end connected to one end of the load 236. The fifth switching unit 246 has one end connected to the negative (-) pole of the second capacitor 235 and the other end connected to the other end of the load 236.

That is, the fourth and fifth switching units 244 and 246 are configured to apply the output voltages V _O1 and V _O2 output from the corresponding rectifying and smoothing circuits to the load 236, while the third switching unit 242 are connected in series to the output ends of adjacent rectifying smoothing circuits among a plurality of rectifying smoothing circuits having a parallel connection configuration so that voltages corresponding to the sum of the output voltages (V _O1 , V _O2 ) output from the adjacent rectifying smoothing circuits To the load (236). 2, two fourth and fifth switching units 244 and 246 corresponding to the rectifying and smoothing circuit are shown. However, the number of switching units corresponding to the rectifying and smoothing circuit is not limited to the number of the secondary windings As shown in FIG. The number of the third switching units 242 for connecting the rectifying smoothing circuits adjacent to each other may be one less than the number of the secondary windings.

The first switching unit 202, the second switching unit 204, the third switching unit 242, the fourth switching unit 244, and the fifth switching unit 246 shown in FIG. An n-channel MOSFET (metal-oxide semiconductor field-effect transistor) having a gate, a source, and a drain, and a diode connected in parallel with the MOSFET between the drain and the source.

Meanwhile, the primary switch controller 250 measures the voltage applied to the load 236, and controls the first switching unit 202 and the second switching unit 230 according to the comparison result between the measured voltage and a predetermined feedback voltage. And outputs PWM signals A and B (260 and 262) for controlling the point of time when the direct current voltage is applied to the primary side through the inverter 204.

The output voltage measuring unit 252 of the primary side switch control unit 250 measures an output voltage Vo applied to the load 236 and the feedback voltage generating unit 254 measures an output And outputs a feedback voltage for feedback control of the voltage Vo. The PWM control unit 256 of the primary side switch control unit 250 generates a PWM control signal for controlling generation of a pulse width modulation (PWM) signal according to the comparison result between the feedback voltage and the output voltage (258). The PWM generation unit 258 outputs the PWM signals A and B (260 and 2562) to the first switching unit 202 or the second switching unit 204 by the PWM control unit 256. The PWM signal A 260 is a switching signal transmitted to the first switching unit 202 and the PWM signal B 262 is a switching signal transmitted to the second switching unit 204. As shown in FIG. 2, the first switching unit 202 and the second switching unit 204 alternately turn on / turn off in response to the PWM signals A and B (260 and 262) ) To control the voltages applied to the first and second main windings 210 and 212 of the primary winding.

The secondary switch controller 270 controls the switches included in the secondary switching unit 240 according to the comparison result between the voltage to be output to the load 236 and a predetermined reference voltage, M1 to M3.

The second-side switch controller 270 includes a digital potentiometer 272 and an analog-to-digital converter 280.

A digital potentiometer 272 receives the digital control signal 271 and outputs an analog signal corresponding to the applied digital control signal 271. Where the digital control signal 271 may be a signal input by a user to control the magnitude of the voltage to be applied to the load 236. [ The digital potentiometer 272 is a variable resistive element controlled through a digital control signal 271. The digital potentiometer 272 is a variable resistive element that is controlled by a digital control signal 271 and supplies an analog signal to the power supply VDD and the low To the ground (GND) voltage input to the terminal, and outputs it through the W (Wiper) terminal 273.

The digital control signal 271 may be applied to the feedback voltage generator 254 that outputs the feedback voltage for feedback control of the output voltage Vo applied to the load 236. The feedback voltage generator 254 may be configured to apply the digital control signal 271 to the feedback voltage generator 254. [ Can also be implemented as a digital potentiometer 272 to output an analog signal as a feedback voltage.

The analog digital converter 280 outputs the analog signal output from the W terminal 273 of the digital potentiometer 272 to the third switching unit 242, the fourth switching unit 244, To a plurality of switch control signals (M1 to M3) for controlling the switch control signal (246). 2, the analog-to-digital converter 280 outputs three switch control signals M1 to M3. However, the analog-to-digital converter 280 is not limited to the number of the secondary windings L (where L is a natural number of 2 or more), 2L-1 switch control signals M1 to M3.

The first switch control signal M1 is transmitted to the gate terminal of the third switching unit 242 to control the third switching unit 242 to turn on and off, The third switch control signal M3 is transmitted to the gate terminal of the fourth switching unit 244 to control the fourth switching unit 244 to turn on and off, And controls the fifth switching unit 246 to turn on / off.

As shown in FIG. 2, a power supply apparatus including a DC-DC converter according to an embodiment of the present invention includes a plurality of secondary windings of a DC-DC converter. When a high voltage is applied to a load, The voltage induced in the secondary windings may be combined and applied to the load. When the low voltage is applied, the voltage induced in the plurality of secondary windings may be selectively applied to the load.

That is, as shown in FIG. 2, the power supply apparatus including the DC-DC converter according to the embodiment of the present invention includes a plurality of DC-DC converters by a single switch control circuit for PWM control, The output voltage of the secondary winding can be individually controlled. Further, by using the plurality of switch control signals (M1 to M3), the output voltages of the plurality of secondary windings can be selectively combined and controlled to be applied to the load. Therefore, not only can the output voltage of the high voltage level that the individual DC-DC converter can not output, but also various combinations of the voltage levels of the Gundam fix 14 Gundam fix 14 output voltage can be output.

3 shows an example of an output voltage of a power supply apparatus including a DC-DC converter according to an embodiment of the present invention.

As described above, the power supply apparatus including the DC-DC converter of the present invention includes a transformer 208 having one primary winding and a plurality of secondary windings, and a plurality of switch controls By controlling the plurality of switching units 242, 244 and 246 through the signals M1 to M3, the voltage induced in each of the plurality of secondary windings can be selectively or combined and output as the output voltage Vo. The plurality of switch control signals M1 to M3 may be varied by the digital control signal 271 applied to the secondary switch control unit 270. [ Thus, the user can vary the voltage level of the output voltage Vo to be applied to the load 236 by varying the digital control signal 271.

When the number of secondary windings is L (L is a natural number equal to or larger than 2), the secondary switch control unit 270 can output 2L-1 switch control signals, and the voltage level of the output voltage Vo is 2L-1 And can be output at N different levels, as shown in FIG. 3, corresponding to the number of possible switch control signals.

In FIG. 3, for example, the output voltage Vo is output at three different voltage levels. 3, only the fourth switching unit 244 is turned on and the third and fifth switching units 242 and 246 are turned off in response to a plurality of switch control signals M1 to M3 at the beginning, Only the circuit applies the first output voltage V _O1 to the load. The digital control signal 271 is changed in response to the user command so that only the fifth switching unit 246 is turned on and the third and fourth switching units 242 and 244 are turned off at the first time point t1, And only the second rectifying smoothing circuit applies the second output voltage (V _O2 ) to the load. 3, it is assumed that the voltage level induced by the third auxiliary winding 218 and the fourth auxiliary winding 218 is lower than the voltage level induced by the first auxiliary winding 214 and the second auxiliary winding 216 Respectively.

On the other hand, at the second time point t2, the output voltage Vo when all the third to fifth switching units 242, 244 and 246 are turned on in response to the plurality of switch control signals M1 to M3. In an ideal case, when all of the third to fifth switching units 242, 244, and 246 are turned on, the output voltage V _O3 is the sum of the first output voltage V _O1 and the second output voltage V _{O2 O1} + V _O2 ). However, in an actual circuit, due to various factors such as the capacitance and charging / discharging performance of the first and second capacitors 234 and 235, the voltage and current amount of the DC voltage source 206, Can be output as a third output voltage (V _O3 ) having a voltage level lower than the sum (V _O1 + V _O2 ) of the output voltage (V _O1 ) and the second output voltage (V _O2 ).

As a result, the present invention can vary the output voltage Vo of the power supply device including the DC-DC converter to any of a wide variety of voltage levels at any time by varying the digital control signal 271.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: first DC-DC converter 110: first transformer
130: first switch control unit 150: second DC-DC converter
160: second transformer 180: second switch control unit
202: first switching unit 204: second switching unit
206: DC voltage source 208: Transformer
210: First sovereign line 212: Second sovereign line
214: first auxiliary winding 216: second auxiliary winding
218: third auxiliary winding 220: fourth auxiliary winding
222, 224, 226, 228: diodes
230: first inductor 234: second inductor
234: first capacitor 235: second capacitor
236: load 242: third switching unit
244: fourth switching unit 246: fifth switching unit
250: primary side switch control unit 270: secondary side switch control unit

Claims (7)

A DC voltage source for generating a DC voltage;
A transformer having one primary winding and a plurality of secondary windings;
A primary side switch unit for alternately applying the DC voltage to both ends of the primary side winding in response to a plurality of PWM signals;
A plurality of rectifying smoothing circuits for rectifying and smoothing a voltage induced in a corresponding secondary winding of each of the plurality of secondary windings;
A secondary side switch for transferring a voltage applied from each of the plurality of rectifying smoothing circuits to a load in response to a plurality of switch control signals or a combination of outputs of rectifying smoothing circuits adjacent to each other among the plurality of rectifying smoothing circuits, part;
A primary side switch control unit for comparing the voltage level of the output voltage delivered to the load with a preset feedback voltage to output the plurality of PWM signals; And
And a secondary switch controller for outputting a plurality of switch control signals in response to a digital control signal applied to vary the voltage level of the output voltage,
Wherein the secondary switch control unit comprises: a digital potentiometer for receiving a digital control signal for adjusting a voltage level of the output voltage to be applied to the load, and outputting an analog signal corresponding to the digital control signal; And
A plurality of voltage output switches included in the secondary side switch unit and a plurality of voltage output switches for controlling at least one circuit-linked switch, And an analog-to-digital converter for outputting the switch control signals,
Wherein the analog-to-digital converter is configured to output 2L-1 switch control signals when the number of secondary windings is L. The DC- 2. The apparatus according to claim 1, wherein the secondary side switch unit
Each of which is connected between a corresponding rectifying smoothing circuit and a corresponding one of the plurality of rectifying smoothing circuits, and which, in response to a corresponding one of the plurality of switch control signals, To a plurality of voltage output switches And
A plurality of rectifying and smoothing circuits connected between output ends of rectifying and smoothing circuits disposed adjacent to each other among the plurality of rectifying and smoothing circuits and responsive to a corresponding switch control signal among the plurality of switch control signals, At least one circuit coupling switch for coupling in series; DC converter according to claim 1 or 2, wherein the DC-DC converter includes a DC-DC converter. delete 2. The apparatus according to claim 1, wherein the primary side switch unit
And a DC voltage source connected between the other end of the DC voltage source and the one end of the primary winding, the DC voltage source being connected between the other of the two primary winding lines of the primary winding, A first switching unit for applying the voltage to one end of the main winding; And
Wherein the first switching unit is connected between the other end of the DC voltage source and the other end of the primary winding, and in response to the second PWM signal of the plurality of PWM signals, the DC voltage is alternately supplied to the other end of the primary winding A second switching unit for applying the second switching signal; DC converter according to claim 1 or 2, wherein the DC-DC converter includes a DC-DC converter. 5. The apparatus of claim 4, wherein the primary side switch control unit
An output voltage measuring unit for measuring a voltage level of the output voltage applied to the load;
A feedback voltage generator for generating a feedback voltage for feedback control of a voltage level of the output voltage;
A PWM controller for comparing the voltage measured by the output voltage measuring unit with the voltage of the feedback voltage and generating a control signal corresponding to the comparison result; And
A PWM generator for varying a duty ratio of the first PWM signal and the second PWM signal in response to the control signal; DC converter according to claim 1 or 2, wherein the DC-DC converter includes a DC-DC converter. The apparatus according to claim 1, wherein each of the plurality of rectifying smoothing circuits
A rectifier connected to both ends of a corresponding secondary winding of the plurality of secondary windings to rectify an AC voltage induced in the secondary winding to DC; And
A smoothing unit for smoothing the voltage rectified by the rectifying unit and outputting the smoothed voltage; DC converter according to claim 1 or 2, wherein the DC-DC converter includes a DC-DC converter. 7. The apparatus according to claim 6, wherein the rectifying part
And two diodes each having one end connected to both ends of the secondary winding,
The smoothing unit
And a capacitor connected in parallel with the inductor between an inductor having one end connected to the other end of the two diodes and two auxiliary windings of the other end of the inductor and the secondary winding. Power supply.

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