KR100828179B1 - multi-phase flyback and forward synchronous rectifier - Google Patents

Abstract

The present invention relates to a synchronous rectification circuit, and in particular, the synchronous rectification circuit is configured in a polyphase by using two primary and secondary transformers of each phase, and the two transformers connected to the primary and secondary sides respectively have polarities. By connecting differently, the present invention relates to a multiphase flyback and forward synchronous rectification circuit suitable for high power transfer density, no output stage inductor, and minimizing output side pulsation voltage.

In the constituent means of the multiphase flyback and forward synchronous rectification circuit of the present invention, in a half bridge power circuit, two transformer primary windings are connected to each other in series with different polarity, and one side is connected to the capacitor neutral point n1, and the other side is Connect to the interconnection point (n2) of the two primary side switches connected in series, the windings of the two secondary side transformers are connected in series with different polarity, and the interconnection point (n3) to the negative terminal of the output capacitor. Each other is connected to one terminal of a secondary switch having an anti-parallel diode structure, respectively, and the other terminal of each secondary switch is connected to the positive terminal of the output capacitor to provide a synchronous rectification circuit for one phase. It is configured, but characterized in that the synchronous rectification circuit is composed of at least two phases.

Rectifier Circuit, Converter, Power Supply

Description

Multi-phase flyback and forward synchronous rectifier

1A and 1B are exemplary diagrams of a conventional synchronous rectification circuit.

2 is a block diagram of a polyphase flyback and forward synchronous rectification circuit according to the present invention.

3A and 3B are schematic diagrams of a synchronous rectification circuit having a structure different from that of FIG.

4A to 4G are circuits for describing an operation mode of a synchronous rectification circuit according to an embodiment of the present invention.

5 is an operation waveform diagram of a synchronous rectification circuit according to an embodiment of the present invention.

The present invention relates to a synchronous rectification circuit, and in particular, the synchronous rectification circuit is configured in a polyphase by using two primary and secondary transformers of each phase, and two transformers connected to the primary and secondary sides respectively have polarities. By connecting differently, the present invention relates to a multiphase flyback and forward synchronous rectification circuit suitable for high power transfer density, no output stage inductor, and minimizing output side pulsation voltage.

Figure 1a shows a conventional synchronous rectification circuit structure of the active clamp method. Zero voltage switching of primary switches S1 and S2 is obtained, and the secondary side adopts a synchronous rectification method to achieve high efficiency.

The circuit shown in FIG. 1A is a structure in which the power transmitted during the switch turn-on is turned into a direct current when viewed from the output side, and a pulsation voltage is generated according to the off period. It is more suitable for the structure with low output current, and the larger the current capacity has the disadvantage of larger filter size.

Figure 1b shows a half-bridge center tap rectified synchronous rectification circuit. On the primary side, the switches S1 and S2 alternately perform a switching operation, so that an AC voltage, which is half of the input voltage, is applied to the transformer. Therefore, the transformer secondary voltage on the output side is alternately rectified through the diode and delivered to the filter.

Accordingly, the rectified voltage in the form of a radio wave appears on the output side. This circuit has a large copper loss due to passive elements, i.e., filter inductor (L), for the output of low voltage and large current, and it is inevitable that the limit and loss of miniaturization by a transformer are inevitable.

In order to compensate for this drawback, a structure using a plurality of secondary windings with an inductor removed was introduced, but there is also an equivalent load-side inductor loss, and secondary and tertiary windings using a center tap rectifying structure are equivalent in a physical transformer configuration. As a current backing circuit structure, copper loss due to large current output is inevitable.

In addition, the method using the current back-up circuit in a form more suitable for large current has been used for a long time and has the advantage of reducing the current pulsation and easy to achieve a large current compared to the simple rectifier circuit. This circuit also uses an inductor at the output stage, so inductor losses due to large currents are inevitable and dynamic losses cannot be avoided.

The present invention was devised to solve the above problems of the prior art, and to minimize the power loss to lower the output voltage and increase the current capacity, and to simplify the structure and minimize the pulsating current through the multi-phase structure It is an object of the present invention to provide a polyphase flyback and forward synchronous rectification circuit capable of minimizing a filter.

In order to solve the above technical problem, the constituent means of the multiphase flyback and forward synchronous rectification circuits of the present invention, in a synchronous rectification circuit, mutually series two transformer primary side windings with different polarities in a half bridge power circuit. One end is connected to the capacitor neutral point (n1),

The other end is connected to the interconnected point (n2) of two primary switches connected in series, the windings of the two secondary transformers are connected in series with different polarity and the interconnected point (n3) is the negative terminal of the output capacitor. The other end of each of the secondary switches is connected to the positive terminal of the output capacitor, each of which is connected to one terminal of the secondary switch having an anti-parallel diode structure. Comprising a rectifier circuit, characterized in that the synchronous rectification circuit is composed of at least two phases.

In addition, a diode is used instead of the secondary switch.

In addition, the at least two or more phases are controlled such that the output current phase difference of each phase is differentiated by dividing one cycle by the number of phases.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of a multi-phase flyback and forward synchronous rectification circuit of the present invention consisting of the above configuration means.

In the present invention, the insulation transformers are arranged symmetrically in directions different in polarity, so that an energy storage operation and an operation of transferring power to a load occur alternately.

When the transformer is described based on the half bridge circuit, the primary is coupled in series with different polarity directions, and the secondary is coupled in parallel with respect to the load. The secondary side transformer consists of a synchronous rectification circuit with a center tap rectifying structure. In particular, it has a large-capacity and more suitable structure for large currents by configuring in a multi-phase form, and the pulsation current is reduced by changing the phase between each phase.

Such a structure can be expanded to form various modified circuits, and can be configured by arranging a plurality of single phase structures in series on the primary side to reduce the high input voltage.

If the current is large in the existing dc-dc power supply, the loss on the output side becomes very large. The structure such as the circuit of Figs. 1A and 1B is difficult to avoid inductor loss and efficiency reduction at light load even when using the synchronous rectification circuit.

In the present invention, in order to improve the high loss and low efficiency at the high current which is the limit of the existing dc-dc power supply, the structure is composed of the inductor on the primary side equivalently, and has the full-wave rectification characteristics. Was to solve.

Until now, we have tried to solve the problem of high current by simply adopting a synchronous rectifier circuit or using a single transformer. However, there are disadvantages of additional inductor loss or poor coupling characteristics due to secondary and tertiary windings in the actual winding structure.

In addition, in order to achieve a higher current, a half bridge structure using only one phase has a limitation. Therefore, it is necessary to increase power density by increasing capacity due to multiphase structure, miniaturization of filter and dissipating heat due to loss.

A configuration of a synchronous rectification circuit according to the present invention that can solve all the above problems is shown in FIG. The configuration of one phase is as follows.

As shown in FIG. 2, in the half bridge power circuit, two primary side transformers T1 and T2 or T3 and T4 are connected in series with different polarities. One of the two primary side transformers connected in series is connected to the capacitor neutral point n1, and the other is connected to the point n2 of the two primary side switches S1 and S2 or S3 and S4 connected in series. Will be wired.

On the other hand, as shown in Figure 2, the windings of the two secondary-side transformer (T1 and T3 or T2 and T4) are connected in series with different polarity and the interconnected point (n3) is the negative terminal of the output capacitor (C ₀ ) The other end of each of the secondary switches (S5 and S7 or S6 and S8) each having an anti-parallel diode structure, the other terminal of each secondary switch being connected to the positive terminal of the output capacitor. Connected.

The structure described above is a structure for one phase. In the present invention, at least two synchronous rectification circuits having such a structure are combined to provide a multiphase synchronous rectification circuit.

The primary side of the polyphase synchronous rectification circuit may be configured as a half bridge structure (see FIG. 3A) or a phase series structure (see FIG. 3B), and two transformers are connected in series with different polarities to form a primary side transformer circuit. The secondary side is composed of synchronous rectification circuit of center tap rectifying structure after the secondary winding of each transformer is connected in series to configure the output. At this time, the output stage inductor is equivalently configured through the primary winding of each transformer in terms of the primary side.

On the other hand, the secondary switch may be replaced by a diode, as shown in Figure 3a and 3b. The structure of FIG. 3B is a circuit modified by extending the circuit of FIG. 2. In order to reduce the high input voltage, the primary side has several switches and transformers arranged in series, and the transformer secondary side is configured in parallel.

4A to 4G are circuits for describing an operation mode of a synchronous rectification circuit according to an embodiment of the present invention, and FIG. 5 is an operation waveform diagram of the synchronous rectification circuit according to an embodiment of the present invention. Referring to this operation of the synchronous rectification circuit of the present invention will be described.

The operation mode illustrated in FIGS. 4A to 4G illustrates a process of changing from the ON states of the switches S1 and S4 to the ON states of the switches S2 and S3. The operating waveform is assuming that there is no dead time of each switch. In the actual operation mode, the conduction period of the diode is shown in consideration of the dead time at the on / off of each switch. For simplicity, we assume that the current through the circuit is continuous.

On the other hand, in order to clarify the operation description of the present invention, the portion in which the conduction or current flow of the element in the circuit shown in Figs. 4A to 4G is indicated by a thick line.

Mode 1 shown in FIG. 4A is in a state where switches S1, S4, S5, and S8 are turned on. Transformers T1 and T4 perform forward operation and deliver power to the output. T2 and T3, on the other hand, fly back and accumulate energy. At this time, the current waveform is shown in FIG. 5, and since T1 and T4 discharge energy stored in the previous mode and forward current increases, current forms such as iT1 and iT4 appear on the secondary side of the transformer.

All transformers have the same current form because current accumulation and forward and flyback discharge modes are repeated. Each current has a phase difference due to the operating phase difference of the switches.

In mode 2 shown in FIG. 4B, S4 is turned off so that the current flowing through T3 and T4 is refluxed through the antiparallel diode of S3. Therefore, S3 can be turned on. The antiparallel diode of S7 also begins to conduct due to the discharge current of T3 induced to the secondary side.

Mode 3 shown in FIG. 4C is a mode in which S7 is turned on. Zero-voltage turn-on occurs because the anti-parallel diode is already on. Also in mode 3, S8 turns off and current iT4 flows through the anti-parallel diode. Therefore, S8 turns off the zero voltage.

In mode 4 shown in FIG. 4D, S3 turns on the zero voltage while the antiparallel diode is turned on. In the secondary rectifier, only S5 and S7 turn on to deliver power to the output through T1 and T3.

In mode 5 shown in FIG. 4E, the current flowing through T1 and T2 when S1 is turned off flows to the antiparallel diode of S2. In the rectifier circuit on the secondary side of the transformer, the antiparallel diode of S6 turns on by the current of T2.

Mode 6 shown in FIG. 4F is a mode in which S6 turns on zero voltage. In Figure 4f too

Since S5 turns off and the anti-parallel diode is turned on, it turns to zero voltage switching.

Mode 7 shown in FIG. 4G turns on the zero voltage while S2 is turned on with the anti-parallel diode turned on. Therefore, S2 and S3 are turned on and S6 and S7 are turned on on the transformer secondary side.

Subsequent operation modes are repeated on the same principle as the previously described operation modes.

On the other hand, the synchronous rectification circuit of the present invention composed of at least two or more phases is controlled so that the output current phase difference of each phase differs by one period by the number of phases.

Specifically, the multiphase control will be described with reference to FIG. 2, which shows a case where two phases are used. Each phase is controlled so that the phase difference is 90 degrees. That is, as shown in the waveform of Fig. 5, iT1 and iT3 and iT2 and iT4 have a phase difference of 90 degrees. Therefore, the summed current of the rectified secondary side becomes smaller as the pulsating currents cancel each other and finally shows a pulsating current equal to iout of FIG. 5 and four times the switching frequency. Therefore, the magnitude of the pulsating current becomes smaller in proportion to the number of superimposed currents, thereby minimizing the filter.

As described above, the present invention can provide a synchronous rectification circuit having a multi-phase structure having a flyback and forward converter operation at the same time to have a full-wave rectification effect to minimize the efficiency and output pulsation.

On the basis of one phase, the synchronous rectification circuit according to the present invention is configured by using two primary and secondary transformers, each configured to flyback or forward operation symmetrically to each other, and to configure the synchronous rectification circuit. It is suitable for low voltage and high current circuits. Therefore, it has a high energy transfer density, no output stage inductor, and is more advantageous for high integration, and the primary side switch enables stable zero voltage switching even at light loads.

According to the multi-phase flyback and forward synchronous rectification circuit of the present invention having the above-described configuration and preferred embodiment, each transformer having primary and secondary windings is separately installed, so that the power transfer density is high, there is no output stage inductor, and in particular, the polyphase structure Due to this, the output pulsation voltage is very small, which has the advantage of minimizing the filter size. Therefore, there is a more advantageous advantage in high integration.

In addition, since the primary side switch is capable of stable zero voltage switching even at light loads, there is an effect having a higher efficiency and power transfer density than the conventional synchronous rectifier circuit structure.

Claims (3)

In the synchronous rectification circuit, In a half-bridge power circuit, two transformer primary windings are connected in series with different polarity, one at the capacitor neutral point (n1) and the other at the interconnect point (n2) of the two primary switches connected in series. Final, The windings of the two secondary transformers are connected in series with different polarity and the interconnected point (n3) is connected to the negative terminal of the output capacitor, each of which is connected to one terminal of the secondary switch, which includes an anti-parallel diode structure. The other terminal of each secondary switch is connected to the positive terminal of the output capacitor, forming a synchronous rectification circuit for one phase, And a synchronous rectification circuit for each of at least two phases. The method according to claim 1, And a diode is used in place of the secondary side switch. The method according to claim 1 or 2, Each synchronous rectification circuit for the at least two phases, And the phase difference of the output current of each phase in the output capacitor is controlled such that the phase difference is divided by one period by the number of phases.

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