KR20000045686A - Multi resonant converter with low voltage stress - Google Patents

Abstract

PURPOSE: An alternating multi resonant converter with two switches is provided to decrease the resonant voltage stress. The apparatus divides the input voltage into a plurality of output voltage so as to make the resonance, which allows the high frequency switching and high efficiency. CONSTITUTION: A multi resonant converter includes a voltage divider(10) which divides the input voltage into a plurality of output voltage, a transformer which adjusts the level of an output voltage. The first and second switches connected between the voltage divider and a transformer(20) provide alternatively the output voltage from the driver to the transformer. The converter has a reset circuit(40), a rectifier(50), a filter(60), and a output port(70), and they are connected in series. One switch is turn on state for the duration of the other is turn off state. Thus each switch operates alternatively.

Description

Multiple resonant converter with low voltage stress

The present invention relates to a multi-resonant converter having a low voltage stress, and in particular, a multi-resonant converter capable of realizing high efficiency and high frequency switching while reducing voltage stress applied to the multi-resonant switch by dividing the magnitude of the input voltage. It is about.

In general, a DC-DC converter converts a direct current into an alternating current and then rectifies the voltage by stepping up or down by a transformer to rectify the DC voltage. The DC-DC converter uses a transistor and a silicon controlled rectifier (SCR). It is divided into

In the above, a multi-resonant converter (MRC) using a transistor as a switching element minimizes parasitic oscillation by using parasitic reactance components present in a circuit in a resonant circuit. Switching is possible.

1 is a circuit diagram showing the configuration of a multiple resonant converter according to the prior art.

Referring to FIG. 1, reference numeral Vs denotes an input voltage supplied to the system from the outside, T denotes a transformer consisting of primary and secondary coils, and Q denotes a switching element connected to the primary coil of the transformer T. L denotes an inductor connected in series with the switching element Q, and C denotes a capacitor connected in parallel with the switching element Q and causing resonance with the inductor L.

In addition, reference numeral 1 denotes a reset portion connected to the output side of the transformer T to automatically reset the transformer T during operation, 2 denotes a rectifying portion converting the output of the transformer T into DC, and 3 Denotes a filter portion for removing unnecessary components, and 4 denotes an output portion of the converter.

In the multi-resonant converter having the above configuration, the voltage supply to the transformer T is determined according to the state of the switching element Q. The inductor L and the capacitor (W) are turned on while the switching element Q is turned on. C) causes resonance.

However, since the resonant circuit of the LC is formed while the switching element Q is turned off during the above operation, high resonant voltage stress appears during resonance.

As a result, in the conventional multi-resonant converter as described above, since the resonance voltage generated for zero voltage switching of the switching element is 4 to 5 times the input voltage, the rated voltage of the switch is increased due to the high voltage stress across the switch. This raises the problem of increasing conduction losses.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and its object is to provide a voltage switching unit that bisects the magnitude of the input voltage and alternately provides a voltage size conversion unit, thereby reducing voltage stress and simultaneously enabling high frequency switching. The present invention provides a multiple resonant converter having low voltage stress.

1 is a circuit diagram of a multiple resonant converter according to the prior art,

2 is a circuit diagram of a multiple resonant converter according to the present invention;

3 is a waveform diagram for explaining the operation of the present invention;

4 and 5 are circuit diagrams showing another embodiment of the present invention.

<Description of the code | symbol about the principal part of drawing>

10: voltage divider 20: voltage magnitude converting unit

31: first switching unit 32: second switching unit

40 reset unit 50 rectifier

60 filter unit 70 output unit

V _S : Power supply unit C _S1 , C _S2 : Input filter capacitor

Q ₁ , Q ₂ : switching element L _R1 , L _R2 : resonant inductor

C _R1 , C _R2 : Resonant Capacitor C _D : Reset Capacitor

D _F1 : forward diode D _F2 : free-wheel diode

L _F : Filtering Inductor C _F : Filtering Capacitor

According to a feature of the present invention for achieving the above object, a voltage divider for dividing the voltage provided from the power supply to a plurality of outputs, a voltage size converter for changing the voltage output from the voltage divider to a desired size; A first and second switching units disposed between the voltage divider and the voltage magnitude converter to sequentially supply the first and second output voltages of the voltage divider to the voltage magnitude converter, and sequentially at an output terminal of the voltage magnitude converter; The present invention provides a multiple resonant converter including a reset part, a rectifier part, and a filter part connected to each other.

At this time, according to an additional feature of the present invention, the first and second switching unit, respectively; An inductor connected in series with the switching element; And a capacitor coupled to the switching element in parallel and causing resonance with the inductor, wherein the switching element of the first switching unit and the switching element of the second switching unit are one while the other is turned on. Are preferably turned off to operate in opposition to each other.

In addition, the voltage size converter is a transformer having a primary coil and a secondary coil, the primary coil is composed of two coils connected 1: 1 to the output terminal of the first and second switching unit. In this case, the secondary coil may be composed of two coils that are connected 1: 1 to the two primary coils.

Hereinafter, exemplary embodiments of a multi-resonant converter having a low voltage stress according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram showing the configuration of a multiple resonant converter according to the present invention.

2, the reference numeral 10 denotes a partial pressure to provide two outputs divided voltage provided from the power supply (V _S), 20 changes the voltage that is output from the voltage-dividing unit 10 to the size that 31 and 32 are disposed between the voltage divider 10 and the voltage size converter 20 to alternately replace the first and second output voltages of the voltage divider 10. The first and second switching units provided to the conversion unit are shown, 40 is a reset unit for performing an automatic reset of the voltage size conversion unit 20, 50 is a DC signal outputting the output of the voltage size conversion unit 20 The rectifier converts to?, 60 denotes a filter for removing unnecessary components, and 70 denotes a load R _L , that is, an output.

In the above-described divider 10, two input filter capacitors C _S1 and C _S2 having the same capacitance are connected in series to divide the input voltage. In addition, the voltage size converter 20 is composed of a transformer having a primary coil (N ₁ , N ₂ ) and a secondary coil (N ₃ ), the primary coil is two coils (N ₁ , N ₂ ) and are connected to the output terminals of the first and second switching units 31 and 32 one by one.

In addition, the first and the second switching unit (31, 32) are each a switching element (Q _1, Q ₂₎ and the switching elements (Q _1, Q ₂₎ resonant inductor connected in series (L _R1, L _R2 ) and resonant capacitors C _R1 and C _R2 connected in parallel to the switching elements Q ₁ and Q ₂ and causing resonance with the resonant inductors L _R1 and L _R2 . In this case, the switching elements Q ₁ and Q ₂ are turned off while the other one is turned on, and thus the opposite operation is performed.

In addition, the forward diode D _F1 and the flyback diode D _F2 constituting the rectifier 50 are turned on / off according to the polarity of the voltage across the reset capacitor C _D of the reset unit 40. In addition, the filter unit 60 is formed by connecting a filtering inductor L _F and a filtering capacitor C _F in series.

The multi-resonant converter of the present invention having the configuration as described above exhibits a waveform as shown in FIG. 3 according to the turn-on / turn-off states of the switching elements Q ₁ and Q ₂ . Is as follows.

Mode 1 (t0 ~ t1): the second switching device of claim 1, the inductor current (i _L1) (Q ₂₎ is a first switching element (Q ₁₎ in the off state having an initial value of the sound is turned ON is the It gradually increases as it flows through the body diode of the first switching element Q ₁ . In this case, the resonant circuit in the second switching element Q ₂ is constituted by a second resonant inductor L _R2 and a second resonant capacitor C _R2 , so that the voltage V between both ends of the second switching element Q ₂ is reduced. _DS2 ) will resonate. When the current i _P flowing through the voltage size converter 20 at resonance flows at zero current, the voltage across the switch V _DS2 reaches a maximum value. At this time, since the secondary voltage V _D of the voltage size converter 20 is a positive initial value, the forward diode D _F1 of the rectifier 50 is energized to supply energy to the output unit 70.

Mode 2 (t1 to t3): When the secondary side voltage V _D resonates and reaches zero voltage due to the resonance of the second resonant inductor L _R2 and the second resonant capacitor C _R2 at t1, the rectifier 50 The forward diode D _F1 ) is blocked, and the energy charged in the filtering inductor L _F of the filter unit 60 supplies energy to the output unit 70 while refluxing through the reflux diode D _F2 . At this time, at t2, the input current i _S resonates, passes through the zero current, and resonates in the negative direction, thereby regenerating energy to the input side.

Mode 3 (t3 to t5): When the voltage V _DS2 of the second switching element Q ₂ resonates and reaches a zero voltage at t3, a negative current i _L2 flowing through the second resonant inductor L _R2 is reached. Flows through the body diode of the second switching element Q ₂ . At t4, the input current i _S resonates and resonates in the positive direction across the zero current.

Mode 4 (t5 to t6): When the secondary voltage V _D of the voltage magnitude converting unit 20 resonates to a positive value, the forward diode D _F1 of the rectifying unit 50 becomes forward and again conducts. do.

Mode 5 (t6 to t7): When the first switching element Q ₁ is turned off and the second switching element Q ₂ is turned on, the current flowing through the second resonant inductor L _R2 having a negative value i _L2 ) gradually increases as it flows through the body diode of the second switching element Q ₂ . In this case, the resonant circuit in the first switching element Q ₁ is constituted by a first resonant inductor L _R1 and a first resonant capacitor C _R1 so that the voltage V between both ends of the first switching element Q ₁ . _DS1 ) will resonate. When the current i _P flowing through the voltage size converter 20 at resonance flows at zero current, both voltages V _DS1 reach a maximum value. At this time, the secondary voltage V _D of the voltage size converter 20 supplies energy to the output unit 70 through the forward diode D _F1 of the rectifier 50 while maintaining a positive value.

Mode 6 (t7 to t10): When the secondary voltage V _D of the voltage magnitude converting unit 20 resonates to a negative value at t7, the forward diode D _F1 of the rectifying unit 50 is blocked, and the filter The energy charged in the filtering inductor L _F of the unit 60 supplies energy to the output unit 70 while refluxing through the reflux diode D _F2 . At this time, the current i _L2 flowing in the second resonant inductor L _R2 at t8 begins to flow through the channel of the second switching element Q ₂ . At t9, the input current i _S resonates to a negative value and regenerates energy to the input side.

Mode 7 (t10 to t12): When the voltage V _DS1 of both ends of the first switching element Q ₁ resonates and reaches a zero voltage at t10, a negative current i _L1 flowing through the first resonant inductor L _R1 Flows through the body diode of the second switching element Q ₁ . At t11, the input current i _S resonates and resonates in the positive direction across the zero current.

Mode 8 (t12 to t13): When the secondary voltage V _D of the voltage magnitude converting unit 20 resonates to a positive value, the rectifying unit 50 until the first switching element Q ₁ is turned on. The forward diode D _{F1 of} is turned on again to supply energy to the output unit 70.

As a result, the two switching elements Q ₁ and Q ₂ operate in opposite directions, and the secondary coils of the voltage size converter 20 alternately receive voltages from the two switching parts 31 and 32. By operating, the secondary coil operates at twice the operating frequency of the primary coil. Therefore, the frequency of the voltage across the reset capacitor C _D connected to the secondary coil of the voltage size converter 20 is twice higher than the frequency of the voltage supplied to the primary side.

On the other hand, the present invention as shown in Figure 4 and 5, by making the secondary coil of the voltage size converter 20 is composed of two coils that are connected 1: 1 to the two primary coils When configuring a closed loop including a control circuit as in the case of FIG. In addition, as shown in FIG. 5, the output terminal of the rectifier circuit connected to each secondary side may be connected to the output terminal of the converter to implement a parallel structure to increase the rating.

In the above description, the present invention has been described using a forward type circuit as an example. However, the technical concept of the present invention can be applied to a flyback type circuit to those skilled in the art to which the present invention pertains. You will know.

As described above, the multi-resonant converter having the low voltage stress according to the present invention is capable of high-frequency switching of several MHz bands by alternately receiving voltages from two switching units, thereby realizing high power density and miniaturizing the product. There is an effect that can achieve the weight reduction.

Claims (4)

A voltage divider for distributing the voltage provided from the power supply to a plurality of outputs; A voltage size converter for changing the voltage output from the voltage divider to a desired size; First and second switching units disposed between the voltage divider and the voltage magnitude converter to alternately provide the first and second output voltages of the voltage divider to the voltage magnitude converter; And a reset unit, a rectifying unit, and a filter unit sequentially connected to an output terminal of the voltage magnitude converting unit. The method of claim 1, Each of the first and second switching units; An inductor connected in series with the switching element; A capacitor coupled to the switching element in parallel and causing resonance with the inductor, The switching element of the first switching unit and the switching element of the second switching unit, while one is turned on (turn-on) while the other is turned off (turn-off) is a low voltage stress, characterized in that the opposite operation Multiple resonant converter. The method of claim 1, The voltage magnitude converting unit is a transformer having a primary side coil and a secondary side coil, wherein the primary side coil has a low voltage stress, characterized in that it is composed of two coils 1: 1 connected to the output terminals of the first and second switching units. Multiple resonant converter. The method of claim 3, wherein The secondary coil is a multi-resonant converter having a low voltage stress, characterized in that consisting of two coils 1: 1 connected to the two primary coils.