KR101441454B1 - Boost converter using soft switching techniques - Google Patents

Abstract

The present invention relates to a boost converter. More specifically, when a switch is turned on, zero-voltage switching is operated and when the switch is turned off, zero-current switching is operated. Therefore, switching loss is minimized and the booster converter can increase efficiency of power conversion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a soft-

More particularly, the present invention relates to a boost converter capable of performing a zero voltage switching operation at a switch turn 'on' and a zero current switching operation at a turn 'off', thereby improving a power conversion efficiency due to minimization of a switching loss To a soft switching boost converter.

To improve power density, the operating frequency of power converters has been steadily increasing, and soft switching techniques such as zero voltage or zero current switching are widely used for higher switching frequencies.

This soft switching technique not only minimizes the transient loss of the hard switching converter but also has the advantages of the conventional PWM converter, so that the power conversion efficiency can be improved and the research for application to various topologies is active.

1, a conventional boost converter 10 includes a boost converter 10 having one end connected to one end of an input power source V _in and an input power source for charging or charging a charged power source The charging inductor 11 is connected to the other end of the input power source and the other end of the charging inductor 11 to interrupt the current flowing in the charging inductor 11, (12) and the charging inductor (11), and the sum of the power charged in the charging inductor (11) and the input power source is output to the output terminal (14) And an output diode (13) for outputting the output signal.

The conventional boost converter 10 first turns on the charging inductor 11 and the switch 12 together with the input power source when the switch 12 is turned on so that the charging inductor 11 The energy of the charging inductor 11 is added to the input power source and is output to the output terminal 14 by the output diode 13. In this case,

That is, the conventional boost converter 10 is a converter capable of boosting the input power and outputting it to the output stage 14.

On the other hand, the conventional boost converter 10 performs a hard switching operation when the switch 12 is turned 'on' or 'off', and this hard switching operation causes a switching loss.

Figure 2 is when the "on" the switch 12 in the "t _0" time to for explaining the switch "on" the loss of a conventional boost converter 10, a both-end voltage (V _q) of the switch 12 The inductor current i _L gradually increases and the current flowing to the switch 12 at the time t ₁ is kept constant and the voltage V _q between both ends of the switch 12 decreases 0 'at the time point of' t ₂ ', and the switch 12 reaches a normal' on 'state.

That is, power loss (W _on ) occurs between time 't ₀ ' and time 't ₂ ', and this loss is called switch 'on' loss.

3 is a graph for explaining the switch 'off' loss of the conventional boost converter 10. When the switch is turned off at time t ₀ , the switch current is maintained while the voltage across the switch is gradually increased , If the voltage of the switch 12 is kept constant at the time t ₁ , the switch current decreases from the time t _{2 and the} time t ₃ to the time t _3, Quot; off " state.

That is, power loss (W _off ) occurs between time 't ₀ ' and time 't ₃ ', and this loss is called switch 'off' loss.

This switching loss (W _on , W _off ) serves as a cause of lowering the power conversion efficiency of the boost converter.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a boost converter capable of minimizing a switching loss.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

In order to accomplish the above object, the present invention provides a charging device comprising a charging inductor having one end connected to one end of an input power source and discharging a charged or charged power source, a second end connected to the other end of the charging inductor, A switch for interrupting a current flowing through the charging inductor to cause the charging inductor to be charged with power or discharge the charged power, and a switch connected to the other end of the charging inductor, A resonance current is allowed to flow between the charging inductor and the switch and the other end of the input power source when the switch is turned on, Voltage switching operation, or when the switch is turned " off ", the charging inductor and the charging inductor The resonance current on the one end and between the input power to the flow position by the soft-switching cell that the switch zero-current switching operation; to provide a boost converter comprising a.

In a preferred embodiment, the soft switching cell includes: a resonance capacitor having one end connected to the end of the charging inductor and the switch; A first resonance inductor having one end connected to the other end of the resonance capacitor and the other end connected to the other end of the input power source and resonating with the resonance capacitor when the switch is turned on; And a first diode connected between the first resonance inductor and the resonance capacitor and causing a resonance current to flow from the first resonance inductor toward the resonance capacitor.

In a preferred embodiment, the soft switching cell has one end connected to the other end of the charging inductor and the other end connected to the end of the resonant capacitor and the switch, and when the switch is turned off, A second resonance inductor resonating with the resonance capacitor; And the other end of the resonance capacitor and one end of the charging inductor are connected to each other, and when the switch is turned off, the charging inductor and the second resonance inductor form a closed loop together with the resonance capacitor, And a second diode for allowing a resonance current to flow from the resonance capacitor toward the charging inductor.

In a preferred embodiment, the first diode and the output diode are turned on when the switch is turned on with the first diode and the second diode 'off', and the resonance capacitor A first mode in which the first resonance inductor resonates and the switch performs a zero voltage switching operation by a resonance current of the first resonance inductor and a current of the second resonance inductor; A second mode in which a current is equal to a current of the second resonant inductor and the charging inductor, a voltage is charged in the resonant capacitor, and a magnitude of the charged voltage becomes equal to a negative voltage magnitude of the input voltage; The second diode is turned on and the first resonance inductor, the first diode, the second diode, the charging inductor, the second resonance inductor, and the switch form a current path, A third mode in which a current of one resonance inductor is discharged to the second resonance inductor and is maintained until a current of the first resonance inductor becomes '0'; And the first diode and the second diode are turned off and the charging inductor, the second resonant inductor, and the switch form a current path of an input current, and the energy is stored in the charging inductor 4 mode.

In a preferred embodiment, when the charging of the charging inductor is completed and the switch is turned off, the second diode is turned on, and the second diode, the charging inductor, the second resonance inductor And the resonance capacitor forms a current path so that the switch performs a zero current switching operation, and the energy of the second resonance inductor is transmitted to the resonance capacitor, and the voltage of the second resonance inductor and the switch Is maintained until the sum of the output voltages of the output terminals becomes equal to the output voltage of the output terminal; A sixth mode in which the output diode is turned on and the second resonance inductor and the resonance capacitor are resonated and the current of the second resonance inductor is maintained to be zero; The second diode is turned off, the first diode is turned on, a resonance current flows in the second resonance inductor, and the currents of the charging inductor and the second resonance inductor are summed, A seventh mode in which the resonance current of the second resonance inductor is maintained until the resonance current becomes '0'; And an eighth mode in which the first diode and the second diode are turned off and power is added to the input power source and the charging inductor, and the output is outputted to the output terminal.

The present invention further provides a power supply device including the boost converter.

The present invention has the following excellent effects.

According to the boost converter of the present invention, a soft switching cell is added to a conventional boost converter to perform a zero voltage switching operation when a switch is turned on and a zero current switching operation is performed when the switch is turned off, There is an effect that loss of power conversion can be minimized.

1 is a diagram illustrating a conventional boost converter,
2 is a diagram for explaining switching " on " loss of a conventional boost converter,
3 is a diagram for explaining switching " off " loss of a conventional boost converter,
FIG. 4 illustrates a boost converter according to an embodiment of the present invention; FIG.
5 to 12 are diagrams for explaining an operation mode of the boost converter according to an embodiment of the present invention,
13 is a waveform diagram of a boost converter according to an embodiment of the present invention.

Although the terms used in the present invention have been selected as general terms that are widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, the meaning described or used in the detailed description part of the invention The meaning must be grasped.

Hereinafter, the technical structure of the present invention will be described in detail with reference to preferred embodiments shown in the accompanying drawings.

However, the present invention is not limited to the embodiments described herein but may be embodied in other forms. Like reference numerals designate like elements throughout the specification.

4, the boost converter 100 according to the embodiment of the present invention includes a charging inductor 11 having one end connected to one end of the input power source V _in and discharging the charged or charged power source ), The other end of the charging inductor 11 is connected to the other end of the input power source, and the current flowing in the charging inductor 11 is interrupted to charge the charging inductor 11, An output diode (13) connected to the other end of the charging inductor (11) for transmitting a sum of the power source of the charging inductor (11) and the input power source to an output terminal, and a switch And a soft switching cell 110 for performing a zero-current switching or a zero-voltage switching operation when the switches 12, 12 are turned on and off.

That is, the boost converter 100 according to an embodiment of the present invention is a topology in which the soft switching cell 110 is added to the booster converter 10 of the related art.

Although not shown, the boost converter 100 of the present invention includes a rectifier circuit for rectifying and receiving an AC power, a bridge or bridge diode for converting DC into AC, a transformer for boosting or forcing voltage, (SMPS: Switching Mode Power Supply).

When the switch 12 is turned on, the soft switching cell 110 causes a resonance current to flow between the end of the charging inductor 11 and the switch 12 and the other end of the input power source, A resonance current flows between the end of the charging inductor 11 and the switch 12 and one end of the input power source when the switch 12 is turned off or when the switch 12 is turned off Causing the switch 12 to perform a zero current switching operation.

The soft switching cell 110 includes a resonance capacitor 111, a first resonance inductor 112, and a first diode 113.

The resonance capacitor 111, the first resonance inductor 112 and the first diode 113 are turned on when the switch 12 is turned on, .

One end of the resonance capacitor 111 is connected to the end of the charging inductor 11 and the switch 12 and when the switch 12 is turned on, Resonates with the switch 112 so that the switch 12 is turned on when the voltage across the switch 12 is '0' to perform the zero voltage switching operation.

One end of the resonance inductor 112 is connected to the other end of the resonance capacitor 111 and the other end is connected to the other end of the input power source. When the switch 12 is turned on, Resonates with the capacitor 111 to cause a resonant current to flow.

The first diode 113 has an anode connected to one end of the resonance inductor 112 and a cathode connected to the other end of the resonance capacitor 111. In the resonance inductor 112, So that a resonant current flows in the direction of the capacitor 111 for the capacitor.

That is, when the switch 12 is turned on, a voltage is formed in the resonance capacitor 111 by a resonance current, and a voltage is not formed at both ends of the switch 12, Is to perform a zero voltage switching operation.

The soft switching cell 110 further includes a second resonant inductor 114 and a second diode 115 to perform a zero current switching operation when the switch 12 is turned off Lt; / RTI >

The second resonant inductor 114 is connected at one end to the charging inductor 11 and at the other end to the end between the resonant capacitor 111 and the switch 12.

The second resonant inductor 114 resonates with the resonant capacitor 111 when the switch 12 is turned off.

The anode of the second diode 115 is connected to the other end of the resonant capacitor 111 and the cathode thereof is connected between the charging inductor 11 and the input power source.

The second diode 115 is connected to the charging inductor 11, the second resonant inductor 114 and the resonant capacitor 111 when the switch 12 is turned off. So that a resonance current flows from the resonance capacitor 111 toward the charging inductor 11.

That is, when the switch 12 is turned off, the resonance current flows from the second resonance inductor 114 to the resonance capacitor 111, and no current flows through both ends of the switch 12 The switch 12 can perform the zero current switching operation.

Hereinafter, the operation mode of the boost converter 100 of the present invention will be described in detail with reference to FIGS. 5 to 12. FIG.

5 illustrates a first mode wherein the first mode is initiated when the switch 12 is 'on' with the first diode 113 and the second diode 115 turned 'off' The resonance capacitor 111 and the first resonance inductor 112 resonate and the resonance current i _Lr1 of the first resonance inductor 112 and the resonance current i _{Lr1 of} the second resonance inductor 114 the voltage across the switch 12 by (i _Lr2) is '0', the switch 12 performs the zero-voltage switching operation.

6 shows a second mode in which the second mode is equal to the currents of the second resonant inductor 114 and the charging inductor 11 and the output diode 13 is turned off And the resonance capacitor 111 is charged with a voltage.

The second mode is terminated when the magnitude of the voltage charged in the resonance capacitor 111 becomes equal to the magnitude of the negative voltage of the input voltage.

7 shows a third mode. In the third mode, the second diode 115 is turned on and the first resonant inductor 112, the first diode 113, the second diode 115, the charging inductor 11, the second resonant inductor 114, and the switch 12 form a current path, and both ends of the resonant capacitor 111 are opened.

At this time, a current sum of the first resonance inductor 112 and the input power source flows through the second resonance inductor 114.

In the third mode, the current of the first resonant inductor 112 is discharged to the second resonant inductor 114, and the current flows to the first resonant inductor 112 to be '0' .

8 shows a fourth mode in which the first diode 113 and the second diode 114 are turned off and the charging inductor 11, The inductor 114 and the switch 12 form a current path of the input current, and energy is stored in the charging inductor 11.

9 shows a fifth mode, wherein the fifth mode is started when charging of the charging inductor 11 is completed and the switch 12 is turned off.

In the fifth mode, the second diode 115 is turned on and the second diode 115, the charging inductor 11, the second resonant inductor 114, and the resonant capacitor The switching element 111 forms a current path so that no current flows to the switch 12 so that the switch 12 performs the zero current switching operation.

Also, in the fifth mode, the voltage of the resonance capacitor 111 gradually increases due to the movement of energy of the second resonance inductor 114, and the second resonance inductor 114 and the switch And the sum of the voltages 12 is equal to the output voltage of the output terminal 14. [

10 shows the sixth mode. In the sixth mode, when the sum of the voltage of the second resonant inductor 114 and the voltage of the switch becomes equal to the output voltage of the output terminal 14, 13 are turned on and the second resonance inductor 114 and the resonance capacitor 111 are resonated and the current is turned off when the second resonance inductor 114 becomes zero.

11 shows a seventh mode in which the second diode 115 is turned off and the first diode 113 is turned on and the second resonant inductor 114 is turned on. A resonance current flows

The currents of the charging inductor 11 and the second resonant inductor 114 are summed and output as the output current of the output terminal 14 and the resonant current of the second resonant inductor 114 is' 0 ".

12 shows an eighth mode. In the eighth mode, the first diode 113 and the second diode 115 are turned off, and the power is supplied to the input power source and the charging inductor 11 And is output to the output stage 13 and operates substantially the same as the switch-off mode of the conventional boost converter.

13 is a waveform diagram of the boost converter 100 according to an embodiment of the present invention. 'I _L1 ' is the current of the charging inductor 11, 'i _Q1 ' is the current flowing in the switch 12 , 'V _Q1' is the voltage across, "i _Lr1 'of the switch 12 is the first current of the resonant inductor (112) for,' i _Lr2" is the second of the resonant inductor 114 for current, " V _cr 'is the voltage of the resonant capacitor 114, and' Gate 'is the gate signal of the switch 12.

Referring to FIG. 13, the voltage across the switch 12 is '0' at the time of 't ₀ ' at which the first mode starts. At this time, since a current starts to flow through the switch 12, The current flowing through the switch 12 is' 0 'at the time t ₄ ' at which the fifth mode starts, and at this time, the current flowing through the switch 12 It is confirmed that zero current switching (ZCS) is performed because the voltage across both ends starts to increase.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

11: Rechargeable inductor 12: Switch
13: output diode 14: output terminal
100: boost converter 110: soft switching cell
111: resonance capacitor 112: first resonance inductor
113: first diode 114: second resonance inductor
115: second diode

Claims (6)

delete delete A charging inductor which is connected to one end of the input power source and discharges the charged or the charged power of the input power source, a current inductor connected to the other end of the charging inductor and the other end of the input power source, And an output diode connected to the other end of the charging inductor for transmitting the sum of the power of the charging inductor and the input power to the output terminal, The boost converter comprising:
When the switch is turned on, a resonance current flows between an end of the charging inductor and the switch and the other end of the input power source to cause the switch to perform a zero voltage switching operation, and when the switch is turned off, And a soft switching cell for causing a resonance current to flow between the charging inductor and the switch and one end of the input power source to cause the switch to perform a zero current switching operation,
The soft switching cell:
A second resonance inductor having one end connected to one end of the charging inductor and the output diode and the other end connected to one end of the switch,
A resonance capacitor having one end connected between the second resonance inductor and the switch;
A first resonance inductor having one end connected to the other end of the resonance capacitor and the other end connected to a terminal between the input power supply and the switch;
A first diode connected between the first resonance inductor and the resonance capacitor to cause a resonance current to flow from the first resonance inductor toward the resonance capacitor when the switch is turned on;
Wherein the resonance capacitor has a first end connected to the other end of the resonance capacitor and the other end connected to the end of the charging inductor and the input power source, And a second diode for allowing a current to flow therethrough,
The second resonant inductor is in a closed loop with the charging inductor, the resonant capacitor, and the second diode when the switch is turned off, resonates with the resonant capacitor,
Wherein the first resonant inductor is in a closed loop with the first diode, the resonant capacitor, and the switch when the switch is turned on, and resonates with the resonant capacitor.
The method of claim 3,
When the switch is turned 'on' with the first diode and the second diode 'off'
The first diode and the output diode are turned on and the resonance capacitor and the first resonance inductor resonate and the resonance current of the first resonance inductor and the current of the second resonance inductor resonate, A first mode in which the switch performs a zero voltage switching operation;
A second mode in which the resonance inductor and the charging inductor are made equal to each other and the voltage is charged in the resonance capacitor and the magnitude of the charged voltage becomes equal to the negative voltage magnitude of the input voltage;
The second diode is turned on and the first resonance inductor, the first diode, the second diode, the charging inductor, the second resonance inductor, and the switch form a current path, A third mode in which a current of one resonance inductor is discharged to the second resonance inductor and is maintained until a current of the first resonance inductor becomes '0'; And
The first diode and the second diode are turned off and the charging inductor, the second resonant inductor, and the switch form a current path of the input current, and the energy is stored in the charging inductor Mode. ≪ / RTI >
5. The method of claim 4,
When the charging of the charging inductor is completed and the switch is turned off,
The second diode is turned on and the second diode, the charging inductor, the second resonance inductor, and the resonance capacitor form a current path so that the switch performs the zero current switching operation, A fifth mode in which the energy of the second resonance inductor is transmitted to the resonance capacitor and is maintained until the sum of the voltages of the second resonance inductor and the switch becomes equal to the output voltage of the output terminal;
A sixth mode in which the output diode is turned on and the second resonance inductor and the resonance capacitor are resonated and the current of the second resonance inductor is maintained to be zero;
The second diode is turned off, the first diode is turned on, a resonance current flows in the second resonance inductor, and the currents of the charging inductor and the second resonance inductor are summed, A seventh mode in which the resonance current of the second resonance inductor is maintained until the resonance current becomes '0'; And
And an eighth mode in which the first diode and the second diode are turned off and power is added to the input power source and the charging inductor and is output to the output terminal.
A power supply comprising the boost converter of any one of claims 3 to 5.

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