KR20100133790A - Single-stage quasi-resonant flyback converter - Google Patents

Abstract

PURPOSE: A single-stage quasiresonant flyback converter is provided to obtain high efficiency by eliminating the soft switching of a switching element and the inverse recovery loss of an outputting diode. CONSTITUTION: An input filtering condenser and a rectifying diode(Dfr1 to Dfr4) are in successive connection with alternating power source(Vi). The output side of a rectifying diode is in connection with a transformer primary winding through a boost inductor(Lb). The anode of a direct current(Cd) is in the neutral point of the transformer primary winding. One end of a switch is in connection with the opposite part of the neutral point. Another end of the switch connects a voltage applied to both ends of the direct current condenser with the cathode of the direct current condenser. The cathode of an output condenser(Co) is in connection of the neutral point of a transformer secondary winding. An output diode is in connection with the neutral point of the transformer secondary winding. The output terminal of the output diode is in connection with the anode of the output condenser.

Description

Single-stage quasi-resonant flyback converter

The present invention relates to a single-stage quasi-resonant flyback converter, and more particularly, to a single-stage quasi-resonant flyback converter having high efficiency by reducing the voltage stress and switching losses of the switch while using fewer components.

In general, the power supply is composed of an AC-DC converter which is a power factor improving unit for harmonic reduction and a DC-DC converter which is an output voltage controller for DC output voltage control. The power factor improving unit improves the power factor to produce a constant output voltage Vs , and the output voltage controller receives the constant output voltage Vs and outputs a desired output voltage Vo .

Most DC-DC converters adopt a pulse width modulation (PWM) converter, which is electrically isolated from the primary and secondary sides of the transformer, centering around the non-isolated DC-DC converter and the transformer where the input and output are not electrically isolated. Divided into isolated DC-DC converters. Isolated DC-DC converters have a forward method that delivers energy when the switch is ON and a flyback method that delivers energy when the switch is OFF.

However, a two-stage structure consisting of an AC-DC converter, a power factor improvement unit, and a DC-DC converter, an output voltage controller for controlling the DC output voltage, is not only complicated in circuit but also costly due to the large number of parts used. Therefore, a single stage converter integrating the power factor improving unit and the output voltage control unit is used. Single-stage flyback converters feature a simple circuit structure and low component count, which can reduce costs.

In the conventional single-stage flyback converter, when the output load is small, the voltage applied to both ends of the DC condenser increases, so that the voltage stress of the switching element is high. In single-stage flyback capacitors, hard-switching of the switching elements increases switching losses, thereby lowering converter efficiency and increasing system noise.

Invented to solve this problem of the present invention, by configuring the converter circuit to return the voltage across the DC capacitor in the flyback converter circuit to the primary winding of the tap transformer, thereby changing the load of the DC capacitor Regardless of the output voltage, the voltage stress of the switch is kept lower than a certain size over a wide input voltage range, and the switch is turned on by detecting the moment when the resonance current becomes zero, thereby reducing the switching loss and removing the reverse recovery loss of the output diode. The objective is to provide a single stage quasi-resonant flyback converter with high efficiency.

The present invention for performing such an object,

In the single-end flyback converter having a single-ended structure integrating the power factor improving unit and the output voltage control unit, the input circuit and the output network is electrically insulated around the tap transformer (T),

 In the input network, rectifying diodes (Dfr1, Dfr2, Dfr3, Dfr4), which converts the input filtering capacitor (Ci) and alternating current (Vi) into direct current, are sequentially connected to the alternating current (Vi), and the rectifying diodes (Dfr1, Dfr2, The output side of Dfr3, Dfr4) is connected to the transformer primary winding through boost inductor (Lb), the anode of DC condenser (Cd) is connected to the neutral point of the transformer primary winding, and on / off the opposite of the neutral point of the transformer primary winding. One end of the switch which can be switched off is connected, and the other end of the switch is connected to the cathode of the DC capacitor Cd, and has a structure for feeding back the voltage of both ends applied to the DC capacitor Cd to the primary winding of the transformer.

The output network has the output diode Do connected to the neutral point of the transformer secondary winding corresponding to the transformer primary winding, and the output diode Do connected to the neutral point of the transformer secondary winding, and the output terminal of the output diode Do It is characterized in that it is configured to be connected to the positive electrode of the capacitor (Co).

The single-stage flyback converter according to the present invention has a single-stage structure incorporating the power factor improving unit and the output voltage control unit, thereby reducing the number of components due to the simple circuit and reducing the cost, and the voltage of the DC capacitor regardless of the load change. It maintains a relatively small size over a wide input voltage range, reducing the voltage stress of the switch and eliminating the soft switching of the switching element and the reverse recovery loss of the output diode.

1 is a circuit diagram of a single stage quasi-resonant flyback converter according to the present invention. The single-stage flyback converter according to the present invention is an isolated DC-DC converter in which an input network and an output network are electrically isolated from a transformer.

The transformer is a tap transformer (T), and the input network is an input filtering capacitor (Ci) for smoothing AC power (Vi) and a rectifying diode (Dfr1, Dfr2, Dfr3, Dfr4) for converting AC power (Vi) into direct current. It is sequentially connected to the far end (Vi), and the output side of the rectifying diodes (Dfr1, Dfr2, Dfr3, Dfr4) is connected to the transformer primary winding through the boost inductor (Lb), and the DC capacitor (Cd) at the neutral point of the transformer primary winding. ) Is connected to the other end of the transformer primary winding, one end of the switch capable of on / off switching is connected, and the other end of the switch is connected to the cathode of the DC capacitor (Cd) and applied to the DC capacitor (Cd) Has a structure of feeding back the voltage of the transformer to the primary winding of the transformer.

In addition, the output network includes an output diode Do connected to the neutral point of the transformer secondary winding corresponding to the transformer primary winding and an output diode Do connected to the neutral point of the transformer secondary winding, and an output terminal of the output diode Do. Is configured to be connected to the anode of the output capacitor (Co). That is, in the single-stage flyback converter according to the present invention, the primary side and the secondary side are electrically insulated from the center of the tap transformer T, and the number of turns of the primary side and the secondary side is NP1, NP2, and NS, respectively. The rectifier diodes that make up the full-bridge rectifier have fast reverse recovery characteristics, convert the AC input voltage into a pulsating voltage, and boost inductance connected to a predetermined portion of the transformer's primary winding. In addition, the DC capacitor is connected to the primary side of the tap transformer (T) to feed back the voltage at both ends to the primary winding.

The single-stage quasi-resonant flyback converter according to the present invention uses a variable frequency control scheme to provide a boundary current mode (CCM: continuous-conduction mode) and a discontinuous-current mode (DCM) boundary condition. It operates in CRM: critical-conduction mode. In this converter, the current iLb of the boost inductor operates as DCM, so that the DC capacitor voltage (Vd) can be maintained at a constant level over a wide input voltage range regardless of the output load change, and it uses the combined winding method of the primary winding of the tap transformer. Therefore, the DC capacitor voltage Vd is fed back to the primary winding of the tap transformer, thereby reducing the voltage stress of the switch by relatively reducing the voltage across the DC capacitor.

 When all the energy stored in the magnetizing inductance of the transformer is released and its current becomes zero, the voltage across the switch is reduced by the resonance between the magnetizing inductance and the parasitic capacitor of the switch. When the switch is turned on and the switch is turned on, the switch is turned on at a low voltage, thereby reducing the loss caused by switching.The converter operates as CRM, so when the switch is turned on, the current of the output diode is zero. By eliminating reverse-recovery loss, the converter is characterized by high efficiency. In addition, single-stage quasi-resonant flyback converters are simple in construction and can save money by using fewer components.

The boost inductor current iLb of the single-stage quasi-resonant flyback converter according to the present invention flows only when the input voltage is greater than the feedback voltage of the direct current capacitor, that is, the voltage applied to the primary winding NP2 of the tap transformer when the switch is turned on, and becomes zero when it is small. . Therefore, assuming that the input voltage is greater than the feedback voltage of the DC capacitor, the operation waveform of the main part of the single-stage quasi-resonant flyback converter according to the present invention is shown in FIG.

Each waveform is the drive signal Vgs of the switch, the voltage VSw across the switch, the current iLb of the boost inductor, the current iLm of the magnetizing inductance, the current iSw of the switch Sw, and the current iDo of the secondary side output diode in one period Ts. When switch Sw conducts from t0 to t1, iLb and iLm increase linearly and reach maximum at t1. In this process, the output diode is reversed, so no current flows through the output diode, and energy is stored in the boost inductor and magnetizing inductance. When the switch is turned off at t1, the output diode is in a forward state, and the stored energy is transferred to the secondary side, and iLm and iLb decrease linearly. When iLb becomes zero at t2, only the energy stored in the magnetizing inductance is output Passed to wealth. At t3, when the current iLm of the magnetizing inductance becomes zero, the voltage across the switch gradually decreases due to the resonance of the magnetizing inductance and the parasitic capacitor of the switch Sw.When the resonant current becomes zero at t4, the half cycle of resonance, that is, the voltage across the switch At this minimum, the switch Sw conducts to reduce the losses due to switching. At this time, iDo is zero, thus eliminating the reverse recovery loss of the output diode.

Although the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited thereto and may be improved or modified by those skilled in the art within the scope of the technical idea of the present invention.

1 is a circuit diagram showing the structure of a single stage quasi-resonant flyback converter according to the present invention.

2 is a waveform diagram illustrating an operation waveform of a single stage quasi-resonant flyback converter according to the present invention.

Claims (2)

In the single-end flyback converter having a single-ended structure integrating the power factor improving unit and the output voltage control unit, the input circuit and the output network is electrically insulated around the tap transformer (T), In the input network, rectifying diodes Dfr1, Dfr2, Dfr3, and Dfr4, which sequentially convert an input filtering capacitor Ci and the AC power source Vi, are sequentially connected to the AC power source Vi, and the rectifying diode Dfr1 is connected. , Dfr2, Dfr3, Dfr4) is connected to the transformer primary winding through a boost inductor (Lb), the anode of the DC capacitor (Cd) is connected to the neutral point of the transformer primary winding, One end of the switch capable of on / off switching is connected to the opposite side of the neutral point, and the other end of the switch is connected to the cathode of the DC capacitor Cd to feed back the voltage of both ends applied to the DC capacitor Cd to the primary winding of the transformer. Structure, The output network includes a cathode of the output capacitor Co connected to the neutral point of the transformer secondary winding corresponding to the transformer primary winding, an output diode Do connected to the neutral point of the transformer secondary winding, and an output terminal of the output diode Do A single stage quasi-resonant flyback capacitor, characterized in that it is configured to be connected to the anode of the output capacitor (Co). The method of claim 1, wherein the single-stage quasi-resonant flyback capacitor has a minimum voltage across the switch due to resonance between the magnetizing inductance and the parasitic capacitor of the switch Sw after the current stored in the magnetizing inductance of the transformer becomes zero. A single-stage quasi-resonant flyback converter characterized in that it detects the moment of operation and conducts the switch (Sw) to reduce the switching loss and eliminates the reverse recovery loss of the output diode.

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