KR101665937B1 - High-voltage series connected bi-directional converter - Google Patents

Abstract

A high voltage series bidirectional converter is disclosed.
A transformer comprising a first blocking winding and a first secondary winding; A first active switch connected to a second end of the one blocking winding to generate an AC voltage from an input power source; A second active switch connected to the second end of the first secondary winding for controlling the transfer of energy from the one shield winding to the first secondary winding; And a second capacitor connected between the first secondary winding and the second active switch for storing energy transferred from the one interrupting winding, wherein the dots of the one interrupting winding are arranged in a direction opposite to the first active switch , The dot of the first secondary winding is located at the first end of the first secondary winding so as to be positioned in the opposite direction to the second active switch A high voltage series bidirectional converter is provided.

Description

HIGH-VOLTAGE SERIES CONNECTED BI-DIRECTIONAL CONVERTER BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a high voltage series bidirectional converter, and more particularly, to a high voltage series bidirectional converter using an isolated bidirectional switched capacitor.

Renewable energy using wind power and solar light, which is attracting attention due to depletion of fossil fuels and climate change, has characteristics of low output voltage and high output variation.

Therefore, in order to overcome the problem of low voltage characteristics and output fluctuation of new and renewable energy, a step-up converter for converting low-voltage energy into usable voltage, or a high-energy storage device used together with a renewable energy generation device, Bidirectional converter is required. Accordingly, various boost converters and converters capable of bi-directional power transfer have been studied.

However, there is a limitation in achieving a high boosting characteristic at the same time as obtaining a high efficiency characteristic in a conventional step-up converter, and there is a problem in that a converter capable of bi-directional power transfer has a low efficiency compared to a production cost.

Korean Patent No. 10-1350575

One aspect of the present invention is a high voltage series bidirectional converter, which can transmit electric power in both directions, has a high step-up ratio, and has a high efficiency of transformer, thereby providing a converter with high efficiency.

According to an aspect of the present invention, there is provided a high voltage series bidirectional converter comprising: a transformer including a first shield winding and a first secondary winding; A first active switch connected to a second end of the one blocking winding to generate an AC voltage from an input power source; A second active switch connected to the second end of the first secondary winding for controlling the transfer of energy from the one shield winding to the first secondary winding; And a second capacitor connected between the first secondary winding and the second active switch and storing energy transferred from the one intercepting winding, wherein a dot of the one intercepting winding is connected to the one interrupting winding and the first The first secondary winding is located at a first end of the one shield winding so that the active switch is located at an unconnected end thereof and the dot of the first secondary winding is connected to the end of the first secondary winding and the second active switch And is located at the first end of the first secondary winding.

The transformer further includes a second secondary winding, a first capacitor connected in parallel with the input power source to store energy of the input power source, A magnetizing inductor connected in parallel with the first capacitor and the one shielding winding to store energy of the input power source; A third active switch connected to the second secondary winding to control energy transfer from the one winding to the second secondary winding; And a third capacitor connected between the second secondary winding and the third switch for storing energy transferred from the one shield winding.

The second capacitor and the third capacitor may be connected in series to output a DC voltage.

When the first active switch is turned on, the second active switch is turned on at the same time to transfer energy from the one shielding winding to the first secondary winding, and rectifies the transferred energy to the second capacitor .

The third active switch turns on when the first active switch is turned off, transfers energy from the one shielding winding to the second secondary winding, and rectifies the transferred energy to the third capacitor .

When energy is transferred from the one shielding winding to the first secondary winding or the second secondary winding, energy is boosted by the turn ratio of the transformer, and when energy is transferred in the reverse direction, the turn ratio of the transformer Energy can be delivered under pressure.

According to another aspect of the present invention, there is provided a high voltage series bidirectional converter comprising: a power source; a first capacitor connected in parallel with the power source, the first capacitor storing the output energy of the power source; A magnetizing inductor connected in parallel to the one shielding winding and the first capacitor for storing energy output from the first capacitor, and a second inductor wound around the magnetizing inductor and the first and second secondary winding, A drain node is connected to a second end of the one shield winding, and a source node is connected to a second end of the first capacitor to perform a turn-on or turn-off operation to convert energy output from the first capacitor into alternating- And a second active switch connected to a drain node of the first secondary winding to reduce the energy stored in the magnetizing inductor A second capacitor connected to the source node of the second active switch and storing the energy transferred from the one blocking winding, and a second capacitor connected to the source of the second active switch, A third active switch connected in series with the second capacitor and performing a turn-on or a turn-off operation to receive energy stored in the magnetizing inductor from the one cut-off winding connected to a drain node of the third active switch, A current sensor connected to the transformer and configured to sense a current flowing in the cut-off of the transformer, and a reference current for comparing the current flowing in the cut-off of the transformer A reference current generator for generating a current from the current sensor; A current controller which receives the reference current from the reference current generator and compares the reference current with a current flowing in one of the cutoffs of the transformer to control a current flowing in one of the cutoffs of the transformer; A gate node of the first active switch, a gate node of the second active switch, and a gate node of the third active switch, And a PWM generator for applying the PWM signal to a gate node of the second active switch and a gate node of the third active switch, wherein a dot of the one blocking winding is connected to the first active switch Said first secondary winding being located at a first end of said one shield winding so that said first secondary winding Dot is located at the first end of said first secondary winding end to be positioned in the first secondary winding and a single stage that is not connected to the second active switch.

The current controller may compare the current flowing in the first active switch received from the current sensor with the reference current received from the reference current generator and output the reference current to the first active switch through the PWM generator Generating a PWM signal for controlling the turn-on or turn-off operation period of the first active switch so that the gate of the first active switch, the gate node of the second active switch, and the third active switch To the gate node.

A PWM signal for controlling the turn-on or turn-off period of the first active switch is generated and applied to the gate node of the first active switch, the gate node of the second active switch and the gate node of the third active switch May be to apply a PWM signal inverted to the gate node of the first active switch and the gate node of the second active switch to the gate node of the third active switch.

The second active switch turns on simultaneously with the first active switch in accordance with the PWM signal to transfer energy from the one shield winding to the first secondary winding and to rectify the transferred energy, Can be transferred to a capacitor.

When the first active switch and the second active switch are turned off according to the PWM signal, the third active switch is turned on to transfer energy from the one shielding winding to the second secondary winding, So that the energy can be rectified and transferred to the third capacitor.

When energy is transferred from the one shielding winding to the first secondary winding or the second secondary winding, energy is boosted by the turn ratio of the transformer, and when energy is transferred in the reverse direction, the turn ratio of the transformer Energy can be delivered under pressure.

According to an aspect of the present invention, since a bidirectional power transfer and an output voltage with a high boosting voltage can be implemented with a small number of active switches, a converter that is economical in terms of cost can be provided.

Also, it is possible to realize a low-size converter by applying an insulated charge pump, and to provide a converter having a higher step-up ratio by connecting the output of the charge pump and the output of the reset circuit in series.

1 is a circuit diagram of a high voltage series bidirectional converter according to an embodiment of the present invention.
2 is a circuit diagram of a high voltage series bidirectional converter according to another embodiment of the present invention.
3 is a circuit diagram of the converter shown in FIG. 2 applied to a tap-boost circuit.
Fig. 4 is an equivalent circuit diagram for obtaining the step-up ratio of the transformer shown in Fig. 2. Fig.
5 is a circuit diagram showing the operation according to the first mode of the transformer shown in Fig.
Fig. 6 is a circuit diagram showing an operation according to the second mode of the transformer shown in Fig. 2; Fig.
7 is a circuit diagram of a high voltage series bidirectional converter according to another embodiment of the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a circuit diagram of a high voltage series bidirectional converter according to an embodiment of the present invention.

Referring to FIG. 1, a DC power source Vsource and a first active switch Qp are included in a transformer included in a converter according to an embodiment of the present invention. A capacitor and a capacitor are connected to a second end of the transformer. And a second active switch Qsc may be included.

The (+) terminal of the DC power supply Vsource located at one of the cut-offs of the transformer is connected to the first end of the one breaker winding Np and the (-) terminal is connected to the source node of the first active switch Qp . In addition, the drain node of the first active switch Qp may be connected to the second end of the blocking coil Np.

A parasitic resistance esr exists between the first end of the capacitor located at the second end of the transformer and the first end of the second end winding Ns and the parasitic resistance esr exists between the second end of the capacitor and the second end winding Ns The source node of the second active switch Qsc may be connected between the second stage and the drain node of the second active switch Qsc may be connected to the second stage of the second stage winding Ns .

Here, one cut-off winding Np of the transformer and the dots of the second-stage winding Ns are located at terminals to which the active switches Qp and Qsc are not connected, so that an ideal transformer operation can be realized. That is, since the first active switch Qp is connected to the second end of one of the cut-off windings Np of the transformer in FIG. 1, the coil can be wound around the first end of the first cut-off winding Np so that the dot is positioned The second active switch Qsc is connected to the second end of the transformer secondary winding Ns so that the coil can be wound around the first end of the second winding Ns so as to locate the dot, Transformer operation can be implemented.

In addition, a converter capable of bi-directional power transfer can be realized by connecting a MOSFET switch, for example, as an active switch, that is, as a transistor unit, at one end and at the other end of the transformer.

When the first active switch Qp and the second active switch Qsc are turned on or off in the converter circuit configuration according to an embodiment of the present invention, the DC power source Vsource, which is one of the blocks of the transformer, And it can be boosted at the transformer turn ratio and transmitted to the second stage of the transformer. Also, the first and second active switches Qp and Qsc can be controlled to transmit energy in the reverse direction, and voltage drop can be performed at this time. Here, the DC power source (Vsource) may be a photocell, and when a photocell is used, a capacitor may be further required to store the output energy of the photocell.

2 is a converter according to another embodiment of the present invention, in which a flyback reset circuit for canceling the magnetic field of the transformer winding included in the converter shown in FIG. 1 is added.

Referring to FIG. 2, one cut-off winding Np, a photovoltaic (PV), a first capacitor Cpv, a magnetization inductor Lm and a first active switch Qp are included in one block of the transformer, The second stage of the transformer may include first and second secondary winding Nsc and Nfb, second and third capacitors Csc and Cfb and second and third active switches Qsc and Qfb.

A photovoltaic (PV) located at one end of the transformer is connected in parallel with a first capacitor (Cpv), and a first end of a magnetizing inductor (Lm) and a cutoff winding (Np) is connected to a first end of the first capacitor Can be connected in parallel. The drain node of the first active switch Qp is connected to the second end of the magnetizing inductor Lm and the one shielding coil Np and the source node of the first active switch Qp is connected to the drain of the first capacitor Qp, Lt; RTI ID = 0.0 > (Cpv). ≪ / RTI >

At this time, the photovoltaic (PV) is an example of an input power source, and various types of power sources can be connected.

A plurality of secondary shortwave Nsc and Nfb are arranged at the second stage of the transformer and a parasitic resistance esr exists between the first end of the first secondary winding Nsc and the first end of the second capacitor Csc A drain node of the second active switch Qsc is connected to the second end of the first secondary winding Nsc and a second active switch Qsc is connected to the second end of the second capacitor Csc. May be connected to the source node.

A drain node of the third active switch Qfb is connected to a second end of the second secondary winding Nfb and a third active switch Qfb is connected to a second end of the third capacitor Cfb. A source node of the second capacitor Csc and a third capacitor Cfb may be connected in series.

Here, the dots of the first cut-off winding Np and the first secondary winding Nsc of the transformer are located at the terminals to which the active switches Qp and Qsc are not connected, so that an ideal transformer can be realized. That is, in FIG. 2, since the first active switch Qp is connected to the second end of the one shielding winding Np of the transformer, the coil can be wound so that the dot is located at the first end of the one shielding winding Np, Since the second active switch Qsc is connected to the second end of the first secondary winding Nsc of the first secondary winding Nsc, the coil is wound so that the dot is located at the first end of the first secondary winding Ns to implement the operation of the ideal transformer .

On the other hand, the dot of the second secondary winding Nfb is located at the end to which the active switch Qfb is connected, so that a flyback reset circuit can be implemented. That is, since the third active switch Qfb is connected to the second end of the secondary winding Nfb of the transformer, the coil is wound so that the dot is located at the second end of the second secondary winding Nfb, Lt; / RTI >

In addition, a converter capable of bi-directional power transfer can be realized by connecting a MOSFET switch, for example, as an active switch, that is, as a transistor unit, at one end and at the other end of the transformer.

In addition, although the transformer of the converter circuit shown in Fig. 2 is an insulated type in which one shield winding and a second stage winding are divided, a circuit connected to the one shield winding and a circuit connected to the second stage winding, A converter applied to a boost circuit can be implemented.

2, AC voltage is generated from the DC voltage of the photovoltaic (PV) in response to the switching operation of the first active switch Qp, Can boost the AC voltage to the transformer turn ratio and deliver it to the second stage of the transformer.

At the second stage of the transformer, when the first active switch Qp is turned on, the second active switch Qsc is also turned on at the same time to receive the energy from the primary winding Np and store it in the second capacitor Csc, When the active switch Qp is turned off, the third active switch Qfb is turned on to receive the energy stored in the magnetizing inductor Lm and store it in the third capacitor Cfb. In addition, a high boosting voltage can be achieved by serially connecting the output voltages of the second capacitor Csc and the third capacitor Cfb. A specific driving method of the converter according to another embodiment of the present invention will be described with reference to FIGS. 4 to 6. FIG.

4 is a circuit diagram for determining a step-up ratio of a transformer included in the converter shown in FIG.

4, one cut-off winding Np, a photovoltaic (PV), a first capacitor Cpv, a magnetizing inductor Lm and a first active switch Qp are included in one block of the transformer included in the converter The second and third secondary switches Nsc and Nfb, the second and third capacitors Csc and Cfb and the second and third active switches Qsc and Qfb may be included at the second end of the transformer.

A photovoltaic (PV) located at one end of the transformer is connected in parallel with a first capacitor (Cpv), and a first end of a magnetizing inductor (Lm) and a cutoff winding (Np) is connected to a first end of the first capacitor Can be connected in parallel. The drain node of the first active switch Qp is connected to the second end of the magnetizing inductor Lm and the one shielding coil Np and the source node of the first active switch Qp is connected to the drain of the first capacitor Qp, Lt; RTI ID = 0.0 > (Cpv). ≪ / RTI >

At this time, the photovoltaic (PV) is an example of an input power source, and various types of power sources can be connected.

A plurality of secondary shortwave Nsc and Nfb are arranged at the second stage of the transformer and a parasitic resistance esr exists between the first end of the first secondary winding Nsc and the first end of the second capacitor Csc A drain node of the second active switch Qsc is connected to the second end of the first secondary winding Nsc and a second active switch Qsc is connected to the second end of the second capacitor Csc. May be connected to the source node.

A drain node of the third active switch Qfb is connected to a second end of the second secondary winding Nfb and a third active switch Qfb is connected to a second end of the third capacitor Cfb. And the second capacitor Cfb and the third capacitor Cfb may be separated to obtain the voltage gain of the transformer.

When the power loss of the parasitic resistance esr is neglected when the transformer is operating normally, the step-up ratio of the second capacitor Csc connected to the first secondary winding Nsc of the transformer is expressed by Equation (1).

In the equation (1), Nsc is the winding ratio of the first secondary winding Nsc of the transformer, and Np is the winding ratio of the primary winding Np of the transformer.

When operating in a continuous mode (CCM) including a first mode according to the turn-on of the first active switch Qp and a second mode according to the turn-off of the first active switch Qp, The step-up ratio of the third capacitor Cfb connected to the second secondary winding Nfb is expressed by the following equation (2).

In the equation (2), Nfb is the turns ratio of the second secondary winding Nfb at the secondary end of the transformer, Np is the turns ratio of the one interrupting coil Np of the transformer, and D is the duty ratio.

2, since the output voltages of the second capacitor Csc and the third capacitor Cfb are connected in series, the step-up ratio of the converter is the sum of the second capacitor Csc and the third capacitor Cfb . When operating in the continuous mode (CCM), the step-up ratio of the converter shown in FIG.

Hereinafter, the boost operation characteristics of the converter circuit configuration shown in Fig. 2 can be described with reference to Figs. 5 and 6. Fig.

The converter according to another embodiment of the present invention includes a first mode according to the turn-on of the first active switch Qp located at one cut-off of the transformer and a second mode according to the turn-off of the first active switch Qp Mode (CCM).

In addition, it can operate in a discontinuous mode (DCM) including the third mode which is the discharge mode after the first mode and the second mode.

First, FIG. 5 shows operation of the first mode according to the turn-on of the first active switch Qp of the converter shown in FIG. In Fig. 5, the dotted line means a section in which no current flows.

5, when the first active switch Qp is turned on, the second active switch Qsc is turned on at the same time and the third active switch Qfb is turned off so that the DC power supply Vpv, Cpv, magnetization inductor Lm, one shielding winding Np and first secondary winding Nsc to transfer energy to the second capacitor Csc.

That is, in the first mode, when the first active switch Qp is turned on, the current applied from the first capacitor Cpv storing the energy of the DC power supply Vpv is supplied to the magnetizing inductor Lm, And can be transmitted to the DC power supply Vpv through the first active switch Qp. In this process, an AC voltage is generated, and energy can be stored in the first capacitor Cpv and the magnetizing inductor Lm.

Further, in the first mode, since the second active switch Qsc is turned on simultaneously with the first active switch Qp, it is possible to prevent the voltage of the first secondary winding Nsc from being excessively boosted due to the turn ratio of the transformer to the first secondary winding Nsc Energy can be delivered. At this time, the AC voltage transferred from the one-side shield winding Np to the first secondary winding Nsc can be rectified through the second active switch Qsc and stored in the second capacitor Csc, ).

6 shows the operation of the second mode according to the turn-off of the first active switch Qp of the converter shown in Fig. In Fig. 6, the dotted line indicates a section in which no current flows.

Referring to FIG. 6, when the first active switch Qp is turned off, the second active switch Qsc is turned off and the third active switch Qfb is turned on, And only the closed circuit formed by the first capacitor Cpv, the magnetizing inductor Lm and the shielding winding Np flows and the secondary winding of the transformer is connected to the winding of the one shielding winding Np and the second secondary winding Nfb Path can be formed and energy can be transferred to the third capacitor Cfb.

That is, in the second mode, when the first active switch Qp is turned off, the DC power supply Vpv and the first capacitor Cpv form a closed circuit so that the first capacitor Cpv stores energy from the DC power supply Vpv .

The magnetizing inductor Lm and the one shielding winding Np form a closed circuit so that the energy stored in the magnetizing inductor Lm can be transferred from the one shielding winding Np to the second secondary winding Nfb .

In the second mode, when the first active switch Qp is turned off, the third active switch is turned on to transfer the boosted energy due to the turn ratio of the transformer from one cut-off winding Np to the second secondary winding Nfb . At this time, the AC voltage transferred from the one-side shield winding Np to the second secondary winding Nfb may be rectified through the third active switch Qfb and stored in the third capacitor Cfb, ).

When the converter shown in FIG. 2 operates in a discontinuous current mode (DCM) including a first mode and a third mode which is a discharge mode after the second mode, in the third mode, the magnetization inductor Lm And the voltage stored in the second capacitor Csc and the third capacitor Cfb in the first mode or the second mode can be output to the output power Vo in the first mode or the second mode have.

7 is a circuit diagram of a high voltage serial bidirectional converter according to another embodiment of the present invention.

7, one cut-off winding Np, a photovoltaic cell PV, a first capacitor Cpv, a magnetizing inductor Lm and a first active switch Qp are included in one of the transformers included in the converter The first and second secondary windings Nsc and Nfb, the second and third capacitors Csc and Cfb and the second and third active switches Qsc and Qfb at the second end of the transformer, A current controller 100, a current controller 200, a reference current generator 300, and a PWM generator 400.

The second and third capacitors Csc and Cfb are connected to the second stage of the transformer. The second and third capacitors Csc and Cfb are connected to the first and second capacitors Cp and Cm, respectively. And second and third active switches Qsc and Qfb.

A photovoltaic (PV) located at one end of the transformer is connected in parallel with a first capacitor (Cpv), and a first end of a magnetizing inductor (Lm) and a cutoff winding (Np) is connected to a first end of the first capacitor Can be connected in parallel. The drain node of the first active switch Qp is connected to the second end of the magnetizing inductor Lm and the one shielding coil Np and the source node of the first active switch Qp is connected to the drain of the first capacitor Qp, Lt; RTI ID = 0.0 > (Cpv). ≪ / RTI >

At this time, the photovoltaic (PV) is an example of an input power source, and various types of power sources can be connected.

A plurality of secondary shortwave Nsc and Nfb are arranged at the second stage of the transformer and a parasitic resistance esr exists between the first end of the first secondary winding Nsc and the first end of the second capacitor Csc A drain node of the second active switch Qsc is connected to the second end of the first secondary winding Nsc and a second active switch Qsc is connected to the second end of the second capacitor Csc. May be connected to the source node.

A drain node of the third active switch Qfb is connected to a second end of the second secondary winding Nfb and a third active switch Qfb is connected to a second end of the third capacitor Cfb. A source node of the second capacitor Csc and a third capacitor Cfb may be connected in series.

Here, the dots of the first cut-off winding Np and the first secondary winding Nsc of the transformer are located at the ends where the active switches Qp and Qsc are not connected, thereby realizing an ideal transformer. That is, since the first active switch Qp is connected to the second end of the transformer's block interrupter Np, the coil can be wound so that the dot is located at the first end of the interrupter winding Np, Since the second active switch Qsc is connected to the second end of the secondary winding Nsc, an ideal transformer can be realized by winding the coil so that the dot is located at the first end of the first secondary winding Ns.

On the other hand, the dot of the second secondary winding Nfb is located at the end to which the active switch Qfb is connected, so that a flyback reset circuit can be implemented. That is, since the third active switch Qfb is connected to the second end of the secondary winding Nfb of the transformer, the coil is wound so that the dot is located at the second end of the second secondary winding Nfb, Lt; / RTI >

In addition, a converter capable of bi-directional power transfer can be realized by connecting a MOSFET switch, for example, as an active switch, that is, as a transistor unit, at one end and at the other end of the transformer.

The current controller 200 is connected to the current sensor 100 that senses the current flowing in one cut of the transformer, the reference current generator 300 and the PWM generator 400, 2, and third active switches Qp, Qsc, and Qfb. At this time, a not gate may be connected between the PWM generator 400 and the third active switch Qfb.

In such a converter circuit configuration, the current sensor 100 senses the current flowing at an arbitrary point of the cutoff of the transformer and transfers it to the current controller 200. The current controller 200 senses The first, second, and third active switches Qp, Qsc, and Qn are compared with the current flowing at any point of the cut-off of the transformer and the reference current Iref generated by the reference current generator 300 through the PWM generator 400, A turn-on or turn-off operation period of the switching element Qfb may be generated and applied.

At this time, since the reference current Iref has a value of + or?, The energy can be transmitted in both directions according to the reference current Iref, or the energy can be transmitted in both directions by the action of the oscillation.

More specifically, the current sensor 100 senses the current flowing at a certain point in the interruption of the transformer and transfers it to the current controller 200, and the current controller 200 detects the current of the transformer The magnitude of the current Isw flowing in the cutoff is compared with the reference current Iref generated in the reference current generator 300 so that the current of the same magnitude as the reference current Iref flows through one cut of the transformer, A duty cycle (duty cycle), which is a turn-on or turn-off operation period of the power supply Qp, can be controlled, or the frequency can be adjusted according to the configuration of the power stage.

That is, the current controller 200 controls the PWM generator 400 via the PWM generator 400 so as to control the current of the same magnitude as the reference current Iref to be applied to the cut-off of the transformer, And a period of the turn-on or turn-off operation of the first active switch Qp can be adjusted by applying the PWM signal to the first active switch Qp.

Meanwhile, when a low level is applied to the first, second, and third active switches Qp, Qsc, and Qfb through the PWM generator 400, the first and second active switches Qp and Qsc are simultaneously The third active switch Qfb may perform a turn-on operation because a not gate is connected between the PWM generator 400 and the third active switch Qfb.

Accordingly, when the first and second active switches Qp and Qsc are simultaneously turned off, the third active switch Qfb is turned on and the circuit connected to the second secondary winding Nfb is connected to the magnetizing inductor Lt; RTI ID = 0.0 > Lm. ≪ / RTI >

Further, the converter according to another embodiment of the present invention transmits the boosted voltage to the transformer when the energy is transferred from one cut of the transformer to the second end with only three active switches Qp, Qsc, and Qfb, A high boosting voltage can be achieved by connecting the output voltages of the second capacitor Csc and the third capacitor Cfb in series and a voltage reduction can be achieved when energy is transferred in the reverse direction.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

100: Current sensor
200: Current controller
300: Reference current generator
400: PWM generator

Claims (12)

A transformer including a primary winding, a first secondary winding, and a second secondary winding;
A first capacitor connected in parallel with an input power source to store energy of the input power source;
A magnetizing inductor connected in parallel with the first capacitor and the one shielding winding to store energy of the input power source;
A first active switch connected to a second end of the one blocking winding to generate an AC voltage from the input power;
A second active switch connected to the second end of the first secondary winding for controlling the transfer of energy from the one shield winding to the first secondary winding;
A second capacitor connected between the first secondary winding and the second active switch to store energy transferred from the one winding;
A third active switch connected to the second secondary winding to control energy transfer from the one winding to the second secondary winding; And
And a third capacitor connected between the second secondary winding and the third active switch for storing energy transferred from the one shield winding,
The second capacitor and the third capacitor are connected in series,
Wherein a dot of the one shielding winding is located at a first end of the one shielding winding so that the one shielding winding and the first active switch are not connected to each other, Wherein the second secondary winding is located at a first end of the first secondary winding so that the secondary winding and the second active switch can be located at an end that is not connected. delete delete The method according to claim 1,
Wherein the second active switch comprises:
Wherein when the first active switch is turned on, energy is transferred from the one shielding winding to the first secondary winding, and the transferred energy is rectified and transferred to the second capacitor. 5. The method of claim 4,
The third active switch,
Wherein when the first active switch is turned off, energy is transferred from the one shielding winding to the second secondary winding, and the transferred energy is rectified and transferred to the third capacitor. 6. The method of claim 5,
When energy is transferred from the one shielding winding to the first secondary winding or the second secondary winding, energy is boosted by the turn ratio of the transformer,
And the energy is transmitted by the turn ratio of the transformer when the energy is transmitted in the reverse direction. Power supply,
A first capacitor connected in parallel with the power supply and storing the output energy of the power supply;
A transformer including a first secondary winding and a second secondary winding connected to the primary winding and a secondary winding connected to the primary winding,
A magnetizing inductor connected in parallel with the first capacitor and storing energy output from the first capacitor,
A drain node is connected to a second end of the magnetizing inductor and the one shielding winding, and a source node is connected to a second end of the first capacitor to perform a turn-on or a turn-off operation to change the energy output from the first capacitor A first active switch for converting into alternating current energy,
A second active switch connected to a drain node of the first secondary winding to perform a turn-on or turn-off operation to receive energy stored in the magnetizing inductor from the one winding;
A second capacitor connected to a source node of the second active switch for storing energy transferred from the one blocking winding,
A third active switch connected to a drain node of the second secondary winding to perform a turn-on or a turn-off operation to receive energy stored in the magnetizing inductor from the one winding,
A third capacitor connected in series with the second capacitor and connected to the source node of the third active switch to store energy transferred from the one blocking winding,
A current sensor which is provided between the first capacitor and the first active switch and senses a current flowing in one cut of the transformer;
A reference current generator for generating a reference current for comparison with a current flowing in a cut-off of the transformer,
And a reference current generator for receiving the reference current from the reference current generator and for comparing the reference current with a current flowing in one of the cutoffs of the transformer, A current controller for controlling a duty cycle of the first active switch so that a current of the same magnitude as the current can flow,
A gate node of the first active switch, a gate node of the first active switch, a gate node of the first active switch, a gate node of the second active switch, and a gate node of the third active switch, And a PWM generator for applying the PWM signal to the gate node of the first active switch, the gate node of the second active switch, and the gate node of the third active switch,
Wherein a dot of the one shielding winding is located at a first end of the one shielding winding so that the one shielding winding and the first active switch are not connected to each other, And a third active switch located at a first end of the first secondary winding so as to be positioned at an end where the second active winding and the second active switch are not connected,
Wherein the energy transfer unit transfers energy from one cut of the transformer to the second end of the transformer according to the value of the reference current, or transmits energy in the opposite direction. delete 8. The method of claim 7,
Further comprising an inversion element provided between the PWM generator and the gate node of the third active switch,
And a PWM signal that is inverted by the inverting element and applied to the gate node of the first active switch and the gate node of the second active switch is applied to the gate node of the third active switch, . 10. The method of claim 9,
Wherein the second active switch comprises:
Voltage serial bidirectional converter that turns on at the same time as the first active switch according to the PWM signal to transfer energy from the one shielding winding to the first secondary winding and rectifies the transferred energy to the second capacitor, . 11. The method of claim 10,
The third active switch,
When the first active switch and the second active switch are turned off according to the PWM signal, energy is transferred from the one shielding winding to the second secondary winding, and the transferred energy is rectified, To-high voltage series bidirectional converter. 12. The method of claim 11,
When energy is transferred from the one shielding winding to the first secondary winding or the second secondary winding, energy is boosted by the turn ratio of the transformer,
And the energy is transmitted by the turn ratio of the transformer when the energy is transmitted in the reverse direction.

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