JP2010252481A - Switching power supply - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a switching power supply capable of reducing power loss in a constant voltage circuit without increasing the number of transformer windings. <P>SOLUTION: The auxiliary power supply of the switching power supply 1 includes: a first DC conversion means D<SB>4</SB>generating a first DC conversion voltage V<SB>1</SB>by changing the induced voltage of the auxiliary winding T<SB>3</SB>into a direct current; a second DC conversion means D<SB>3</SB>, C<SB>3</SB>boosting the induced voltage to a second DC conversion voltage V<SB>2</SB>higher than the first DC conversion voltage V<SB>1</SB>while changing the induced voltage into a direct current; and a constant voltage circuit 5 outputting a second boosted DC conversion voltage V<SB>2</SB>, while restricting the conversion voltage so as not to exceed a predetermined voltage. When the induced voltage of the auxiliary winding T<SB>3</SB>rises, and a voltage is supplied to an active filter control circuit 4 from the constant voltage circuit 5 prior to voltage supply from the first DC conversion means D<SB>4</SB>, and then the first DC conversion voltage V<SB>1</SB>exceeds the output voltage V<SB>3</SB>from the constant voltage circuit 5, the operation of the constant voltage means 5 is stopped and a voltage is supplied from the first DC conversion means D<SB>4</SB>to the active filter control circuit 4. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a switching power supply device, and more particularly to a switching power supply device that generates a DC auxiliary voltage for supplying a power supply voltage to a control circuit that controls an active filter based on an induced voltage of an auxiliary winding.

  For example, a switching power supply shown in FIG. 3 is used as a world-wide switching power supply device that rectifies a commercial AC voltage and then supplies it to an active filter to improve the power factor and can be used in various commercial AC voltages around the world. The device is known.

As shown in FIG. 3, the switching power supply 10 includes a rectifier (diode bridge circuit D) that rectifies a commercial AC voltage V _ACIN (85 to 132 V / 187 V to ₂₆₄ V) supplied from a 100 V / 200 V commercial AC power source. ₁ ) with. The output voltage of the diode bridge circuit D ₁ is supplied to the active filter 2.

The active filter 2 has switching means connected between the output terminals of the diode bridge circuit D ₁ via a reactor such as a choke, and the switching operation of this switching means is controlled by a control signal from the active filter control circuit 4. The According to the active filter 2, by a sinusoidal shape the output voltage of the diode bridge circuit D _1, it is possible to improve the power factor.

Between the output terminal of the active filter 2, and smoothing capacitor C _1, the primary winding T ₁ and switching means of the transformer T (e.g., power FETs Q ₁₎ series circuit is connected comprising a drain-source conduction path of ing. A control signal from the DC-DC converter control circuit 3 is input to the gate of the power FET Q ₁ . As a result, the conduction period of the power FET Q ₁ is controlled, and the switching voltage is supplied to the primary winding T ₁ .

The transformer T has a secondary winding T ₂ , and one end thereof is connected to the anode of a diode D ₂ that forms a rectifying means. The cathode of the diode D ₂ is connected to one end of a smoothing capacitor C ₂ that forms a smoothing means, and the other end of the smoothing capacitor C ₂ is connected to the other end of the secondary winding T ₂ . From both ends of the smoothing capacitor C ₂ , a DC secondary output voltage V _DCOUT to be supplied to a load (not shown ₎ is output.

As shown in FIG. 3, the transformer T includes an auxiliary winding T ₃ in addition to the primary winding T ₁ and the secondary winding T ₂ . Auxiliary winding T ₃ is wound on the core the same polarity ₁ and the primary winding T on of the transformer T, are connected in series is not shown in FIG. 3 the primary winding T _1. In the following description, of the two ends of the auxiliary winding T ₃ , the end connected to the primary winding T ₁ is called an “interconnect end”, and the opposite end Is referred to as a “non-interconnect end” (the end on the side marked with ● in FIG. 3).

For example, Non-Patent Document 1 discloses an auxiliary power supply unit that generates an auxiliary voltage V ₄ that is a power supply voltage of the DC-DC converter control circuit 3 and the active filter control circuit 4 based on the induced voltage of the auxiliary winding T _3. a constant voltage circuit 5 and the diode D ₆ described is provided. The anode of the diode D ₆ is connected to the non-interconnection end of the auxiliary winding T ₃ , and the cathode of the diode D ₆ is connected to the collector of the transistor Q ₂ constituting the constant voltage circuit 5.

The base of the transistor Q ₂ is connected to the cathode of a constant voltage element (for example, a Zener diode ZD), and the anode of the Zener diode ZD is connected to the interconnection terminal of the auxiliary winding T ₃ . Between the collector and the base of the transistor Q ₂ is the resistor R is connected and an emitter connected to one end of the smoothing capacitor C _4. The other end of the smoothing capacitor C ₄ is connected to the interconnection end of the auxiliary winding T ₃ .

An auxiliary voltage V _{4 serving as} a power supply voltage for the DC-DC converter control circuit 3 and the active filter control circuit ₄ is output from both ends of the smoothing capacitor C ₄ .

As described above, the commercial AC voltage V _ACIN input to the switching power supply 10 fluctuates in a wide range of _85V to 264V. According to the switching power supply 10, the induced voltage of the auxiliary winding T ₃ increases to some extent. The Zener diode ZD becomes conductive, and the auxiliary voltage V ₄ is limited. As a result, damage to the DC-DC converter control circuit 3 and the active filter control circuit 4 due to the supply of overvoltage is prevented.

FIG. 4 shows a switching power supply device obtained by improving and developing the switching power supply device 10 (see, for example, Patent Document 1). As shown in this figure, in the switching power supply device 11, the constant voltage circuit 5 operates only immediately after the start of the input of the commercial AC voltage V _ACIN , and then the constant voltage circuit 5 stops. . Therefore, according to this switching power supply device 11, loss generation in the constant voltage circuit 5 can be reduced.

More specifically, in the switching power supply unit 11, the transformer T has a primary winding T _1, in addition to two auxiliary winding T ₃ of the secondary winding T _2, T _4. Auxiliary winding T _3, T ₄ is wound in the same polarity ₁ and the primary winding T on the core of the transformer T, not shown in FIG. 4 but the primary winding T ₁ and the auxiliary winding T ₃ is connected in series. In the following description, of the two ends of the auxiliary winding T ₃ , the end connected to the primary winding T ₁ is called an “interconnect end”, and the opposite end Is referred to as a “non-interconnection end” (the end on the side marked with ● in FIG. 4). Of the two ends of the auxiliary winding T ₄ , the end connected to the auxiliary winding T ₃ is called an “interconnect end”, and the opposite end is set as “non-interconnect”. It will be referred to as the “end” (the end on the side marked with ● in FIG. 4).

The auxiliary power unit is mainly a constant voltage circuit 5 and a diode D ₆ is provided. The anode of the diode D ₆ is connected to the non-interconnection end of the auxiliary winding T ₄ , and the cathode of the diode D ₆ is connected to the collector of the transistor Q ₂ constituting the constant voltage circuit 5.

The base of the transistor Q ₂ is connected to the cathode of the Zener diode ZD, and the anode of the Zener diode ZD is connected to the interconnection end of the auxiliary winding T ₃ . Between the collector and the base of the transistor Q ₂ is the resistor R is connected and an emitter connected to one end of the smoothing capacitor C ₄ via the diode D ₅ connected in the forward direction. The non-interconnection end of the auxiliary winding T ₃ is also connected to one end of the smoothing capacitor C ₄ via a diode D ₄ connected in the forward direction. The other end of the smoothing capacitor C ₄ is connected to the interconnection end of the auxiliary winding T ₃ .

An auxiliary voltage V _{4 serving as} a power supply voltage for the DC-DC converter control circuit 3 and the active filter control circuit ₄ is output from both ends of the smoothing capacitor C ₄ .

As shown in FIG. 5, when the input of the commercial AC voltage V _ACIN is started at time t _{0 and} the output voltage V ₀ of the active filter 2 rises, the induced voltage of the auxiliary winding T ₃ is accordingly increased by the diode D ₄ . The voltage V ₂ (= input voltage of the constant voltage circuit 5) obtained by converting the sum of the voltage V ₁ converted to DC and the induced voltage of the auxiliary winding T ₃ and the auxiliary winding T ₄ by the diode D ₆ also increases. As apparent from the comparison between FIGS. 5B and 5C, since the voltage V ₂ has a higher rate of increase than the voltage V ₁ , the diode D ₅ becomes conductive and is smoothed by the output voltage V ₃ of the constant voltage circuit 5. Capacitor C ₄ is charged. Then, the auxiliary voltage V ₄ rises in a relatively short time to a voltage necessary for normal operation of the DC-DC converter control circuit 3 and the active filter control circuit 4.

After that, at time t ₁ , when the Zener diode ZD becomes conductive, the output voltage V ₃ of the constant voltage circuit 5 is maintained at a constant voltage V _ZD without increasing further. When the induced voltage of the auxiliary winding T ₃ continues to increase and the voltage V ₁ exceeds the voltage V ₃ at time t ₂ , the diode D ₄ becomes conductive. Then, the smoothing capacitor C ₄ is charged through the diode D ₄ .

The diode D ₅ is turned off, and operation of the constant voltage circuit 5 is stopped. Therefore, thereafter, no loss occurs in the constant voltage circuit 5.

Japanese Patent Laid-Open No. 2001-16851

Practical Electronic Circuit Handbook 1 “Constant Voltage Circuit Combined with Transistor”, CQ Publishing Co., Ltd., September 1972, p. 375, FIG.

By the way, in general, the number of windings that can be provided in a transformer used in a switching power supply device is often limited by the size and other factors. In this regard, in the conventional switching power supply device 11 shown in FIG. 4, in order to generate _two voltages V ₁ and V ₂ having different rates of increase, the transformer T has a primary winding T ₁ and a secondary winding T ₂ . In addition, it is necessary to provide two auxiliary windings (T ₃ , T ₄ ). Therefore, the conventional configuration shown in FIG. 4 cannot be applied to a switching power supply apparatus that must use a small transformer.

  Therefore, an object of the present invention is to provide a switching power supply device that can reduce power loss in a constant voltage circuit without increasing the number of windings of a transformer.

  In order to solve the above-described problems, a switching power supply according to the present invention controls an active filter to which a primary DC voltage obtained by rectifying and smoothing an AC voltage input from the outside is supplied, and the active filter. An active filter control circuit; switching means for switching an output voltage output from the active filter to generate a switching voltage; a primary winding, a secondary winding, and the primary side DC connected in series to the primary winding A transformer having an auxiliary winding whose induced voltage rises as the voltage rises, and that supplies the switching voltage to the primary winding, and rectifies and smoothes the voltage induced in the secondary winding to generate a direct current. Output voltage generating means for generating a secondary side output voltage of the auxiliary winding, and generating a DC auxiliary voltage based on the induced voltage of the auxiliary winding to generate the auxiliary voltage An auxiliary power supply unit that supplies the active filter control circuit as a power supply voltage, wherein the auxiliary power supply unit is interposed between the auxiliary winding and the active filter control circuit, A first DCing means capable of generating a first DC voltage by converting the induced voltage of the auxiliary winding into a DC, and supplying the first DC voltage as the auxiliary voltage to the active filter control circuit; A second DC conversion means connected to the auxiliary winding, which converts the induced voltage of the auxiliary winding to DC and boosts the voltage to a second DC voltage that is higher than the first DC voltage; A constant voltage converting means capable of supplying a second DC voltage to the active filter control circuit while limiting the second DC voltage so as not to exceed a preset voltage, and the output voltage of the active filter When the induced voltage of the auxiliary winding rises as the voltage rises, the voltage is supplied from the constant voltage converting means to the active filter control circuit prior to the voltage supply from the first DC converting means, and then the first When the DC voltage exceeds the output voltage from the constant voltage means, the operation of the constant voltage means is stopped and the voltage is supplied from the first DC means to the active filter control circuit. Features.

According to the above configuration, the power supply voltage can be supplied to the active filter control circuit from the first direct current conversion unit that converts the induced voltage of the auxiliary winding into a direct current and the constant voltage conversion unit. Here, to the constant voltage converting means, the induced voltage of the auxiliary winding is converted into a direct current by the second direct current converting means, and a second direct current voltage higher than the first direct current voltage is input. . The constant voltage means can supply the second DC voltage to the active filter control circuit while limiting the second DC voltage so as not to exceed a preset voltage.
When the induced voltage of the auxiliary winding rises with the increase of the output voltage of the active filter, the voltage is supplied from the constant voltage means to the active filter control circuit prior to the voltage supply from the first DC means. The auxiliary voltage can be rapidly increased at the time of start-up, and the operation of the active filter control circuit using the voltage as the power supply voltage can be started early. In addition, since the auxiliary voltage is limited by the constant voltage control means so as not to exceed the predetermined voltage, even when the range of the AC voltage input from the outside is wide, the auxiliary voltage is prevented from becoming excessively high. A power supply voltage can be stably supplied to the control circuit.
Furthermore, when the first DC voltage exceeds the output voltage from the constant voltage unit, the operation of the constant voltage unit is stopped and the voltage is supplied from the first DC unit to the active filter control circuit. The power consumption of the constant voltage means can be reduced. That is, after the start-up is completed without having to raise the auxiliary voltage rapidly, the operation of the constant voltage unit stops and the power loss in the constant voltage unit can be reduced. In addition, since the above operation is realized by a single auxiliary winding, the transformer can be miniaturized without increasing the number of windings of the transformer.

Further, the second direct current means of the switching power supply device, specifically, the anode is connected to the interconnection end where the auxiliary winding and the primary winding are mutually connected among the ends of the auxiliary winding. A diode and a capacitor having one end connected to the cathode of the diode and the other end connected to a non-interconnection end different from the interconnection end of both ends of the auxiliary winding; It can be configured by connecting to.
Further, the first direct current means has an anode connected to the non-interconnect end where the auxiliary winding and the primary winding are connected to each other, and the cathode connected to the active filter control circuit. It can be composed of a diode.

  Further, the predetermined voltage can be easily set by the breakdown voltage of the Zener diode.

  According to the present invention, it is possible to provide a switching power supply apparatus that can reduce power loss in a constant voltage circuit without increasing the number of windings of a transformer.

1 is a circuit diagram of a switching power supply device according to the present invention. It is the graph which simplified each part voltage waveform of the switching power supply device shown in FIG. It is a circuit diagram of the conventional switching power supply device. It is a circuit diagram of the conventional switching power supply device. It is the graph which simplified each part voltage waveform of the switching power supply device shown in FIG.

  Hereinafter, a preferred embodiment of a switching power supply device according to the present invention will be described with reference to FIGS. 1 and 2. In FIG. 1, the components denoted by the same reference numerals as those in FIG. 3 are the same as those described in the related art, and thus the description thereof is omitted here.

As shown in FIG. 1, in the switching power supply device 1 according to the present invention, the transformer T includes one auxiliary winding T ₃ in addition to the primary winding T ₁ and the secondary winding T ₂ . The auxiliary power supply section is constituted by the auxiliary winding T ₃ , the constant voltage circuit 5 as a constant voltage means, the capacitor C _3, and the plurality of diodes D _{3 to} D ₅ . Auxiliary winding T ₃ is wound on the core to the primary winding T ₁ the same polarity as the transformer T, are connected in series is not shown in Figure 1 the primary winding T _1. In the following description, of the two ends of the auxiliary winding T ₃ , the end connected to the primary winding T ₁ is called an “interconnect end”, and the opposite end Is referred to as a “non-interconnection end” (the end on the side marked with ● in FIG. 1).

In the auxiliary power supply, the anode of the diode D ₄ for rectifying the induced voltage of the auxiliary winding T ₃ (corresponding to "first DC means" of the present invention) is connected to the non-interconnected ends of the auxiliary winding T ₃ The cathode is connected to the power supply terminals of the DC-DC converter control circuit 3 and the active filter control circuit 4. For this reason, the diode D ₄ uses the auxiliary voltage (corresponding to the “first DC voltage” of the present invention) generated by converting the induced voltage of the auxiliary winding T ₃ as a DC power supply voltage as a DC-DC converter control circuit 3. And the active filter control circuit 4 can be supplied.

On the other hand, the anode of the diode D ₃ is connected to the interconnection end of the auxiliary winding T ₃ , and the cathode is connected to the collector of the transistor Q ₂ constituting the constant voltage circuit 5. The cathode of the diode D ₃ is connected to one end of the capacitor C _3, the other end of the capacitor C ₃ is connected to the non-interconnected ends of the auxiliary winding T _3. The diode D ₃ and the capacitor C ₃ convert the induced voltage of the auxiliary winding T ₃ to DC and a voltage higher than the first DC voltage V ₁ (corresponding to the “second DC voltage” of the present invention). Boost the pressure. In this way, the diode D ₃ and the capacitor C ₃ constitute the “second direct current means” of the present invention.

The base of the transistor Q ₂ constituting the constant voltage circuit 5 is connected to the cathode of the Zener diode ZD, and the anode of the Zener diode ZD is connected to the interconnection terminal of the auxiliary winding T ₃ . Resistor R is connected between the collector and the base of the transistor Q _2. The emitter of the transistor Q ₂ is connected the anode of a diode D _5, the cathode of the diode D ₅ is connected to one end of the smoothing capacitor C _4. Diode D ₅ prevents the reverse voltage is applied to the transistor Q _2. The other end of the smoothing capacitor C ₄ is connected to the interconnection end of the auxiliary winding T ₃ .

Further, the cathode of the diode D ₄ is connected to one end of the smoothing capacitor C ₄ . That is, one end of the smoothing capacitor C _4, is connected to the cathode of the cathode and the diode D ₅ of the diode D _4, a smoothing capacitor C ₄ via the diode D ₄ from the auxiliary winding T ₃ fed The first DC voltage V ₁ and the output voltage V ₃ of the constant voltage circuit 5 supplied via the diode D ₅ are selectively charged.

As a result of this charging, an auxiliary voltage V _{4 serving as} a power supply voltage for the DC-DC converter control circuit 3 and the active filter control circuit ₄ is generated at both ends of the smoothing capacitor C ₄ . As shown in FIG. 1, the constant voltage circuit 5 includes a voltage obtained by converting the induced voltage of the auxiliary winding T ₃ into a direct current by the diode D ₃ and the voltage across the capacitor C ₃ , that is, a second direct current. The voltage (second DC voltage) V ₂ boosted higher than the first DC voltage is input by the conversion means.

  Then, with reference to FIG. 2, the operation | movement at the time of starting of the switching power supply device 1 which concerns on this invention is demonstrated.

As shown in FIG. 2, when the input of the commercial AC voltage V _ACIN is started at time t _{0 and} the output voltage V ₀ of the active filter 2 starts to rise, the induced voltage of the auxiliary winding T ₃ rises accordingly. start. At the same time, the capacitor C ₃ is charged via the diode D ₃ . As the, V ₂ (input voltage of the constant voltage circuit 5) second direct current voltage, a first direct current voltage V ₁ and a capacitor C that DC the induced voltage of the auxiliary winding T ₃ in the diode D _{3 3} is the sum of the voltages at both ends. Accordingly, as is apparent from the comparison between FIGS. 2B and 2C, the second DC voltage V ₂ rises more rapidly than the first DC voltage V ₁ . Then, the diode D ₅ is turned, the smoothing capacitor C ₄ is charged by the output voltage V ₃ of the constant voltage circuit 5, the auxiliary voltage V ₄ increases. That is, when the induced voltage of the auxiliary winding T ₃ rises as the output voltage V ₀ of the active filter 2 rises, the constant voltage circuit 5 to the DC-DC converter control circuit prior to voltage supply via the diode D _4. 3 and the active filter control circuit 4 are supplied with a power supply voltage.

As the second DC voltage V ₂ continues to rise, the reverse bias voltage of the Zener diode ZD also rises accordingly. At time t ₁ , the second DC voltage V ₂ exceeds the breakdown voltage V _ZD of the Zener diode ZD, and the Zener diode ZD becomes conductive. Therefore, even if the second DC voltage V ₂ continues to increase, the output voltage V ₃ of the constant voltage circuit 5 is maintained at a constant voltage (≈V _ZD ) without increasing further. Note that the breakdown voltage V _ZD is set higher than the minimum voltage necessary for normal operation of the DC-DC converter control circuit 3 and the active filter control circuit 4. That is, the constant voltage circuit 5 supplies the second DC voltage V ₂ to the DC-DC converter control circuit 3 and the active filter control circuit 4 as a power supply voltage while limiting the second DC voltage V ₂ so as not to exceed a preset voltage. It is possible.

Thereafter, the induced voltage of the auxiliary winding T ₃ is further increased, at time t ₂ when the first direct current voltage V ₁ is greater than the output voltage V ₃ of the constant voltage circuit 5, the diode D ₄ instead of the diode D ₅ Becomes conductive. Thereafter, the smoothing capacitor C ₄ is charged by the voltage (first DC voltage) V ₁ supplied via the diode D ₄ .

On the other hand, when the diode D ₅ is turned off, the operation of the constant voltage circuit 5 is stopped. Therefore, never power loss occurs at time t ₂ later, the constant voltage circuit 5.

Thereafter, when the output voltage V ₀ of the active filter 2 is stabilized at time t ₃ , the first DC voltage V ₁ becomes constant at the voltage V _T3 . The auxiliary voltage V ₄ supplied to the DC-DC converter control circuit 3 and the active filter control circuit 4 is also constant at a voltage substantially equal to the voltage V _T3 .

That is, in the switching power supply device 1 according to the present invention, immediately after startup, the output voltage of the constant voltage circuit 5 (second DC voltage V ₂ is limited by the constant voltage circuit 5 so as not to exceed the predetermined voltage) V _3. charging of the smoothing capacitor C ₄ using is performed, the auxiliary voltage V ₄ increases rapidly. After that, when the induced voltage of the auxiliary winding T ₃ rises, the operation of the constant voltage circuit 5 stops, and the smoothing capacitor C ₄ is charged using the first DC voltage V _1. Is called. Thereby, it is possible to prevent the power loss due to the operation of the constant voltage circuit 5 after the start-up is completed (after time t ₂ ). In addition, since the above operation is realized by a single auxiliary winding T ₃ , it is possible to reduce the size of the transformer without increasing the number of windings of the transformer.

The preferred embodiment of the switching power supply device according to the present invention has been described above, but the present invention is not limited to this embodiment.
For example, in the switching power supply device 1 shown in FIG. 1, the auxiliary voltage V ₄ is supplied to the DC-DC converter control circuit 3 and the active filter control circuit 4, but may be supplied only to the active filter control circuit 4.

The diode D _5, the emitter of the transistor Q ₂ - is intended to prevent a reverse bias is applied to between the base, in such a case concerned is not can be omitted.

The constant voltage circuit 5 can be replaced with another known constant voltage circuit that satisfies the following conditions.
Condition 1: An output voltage substantially equal to the input voltage is output until the input voltage exceeds a predetermined voltage (for example, the breakdown voltage V _ZD ).
Condition 2: When the input voltage exceeds the predetermined voltage, an output voltage substantially equal to the predetermined voltage is output regardless of the input voltage.

DESCRIPTION OF SYMBOLS 1 Switching power supply device 2 Active filter 3 DC-DC converter control circuit 4 Active filter control circuit 5 Constant voltage circuit T Transformer T ₁ Primary winding T ₂ Secondary winding T ₃ Auxiliary winding

Claims (4)

An active filter to which a primary DC voltage obtained by rectifying and smoothing an AC voltage input from the outside is supplied;
An active filter control circuit for controlling the active filter;
Switching means for generating a switching voltage by switching the output voltage output from the active filter;
A primary winding, a secondary winding, and an auxiliary winding connected in series to the primary winding, the induced voltage of which increases as the primary side DC voltage increases, and the switching voltage is applied to the primary winding. A transformer to be supplied,
Output voltage generating means for generating a DC secondary output voltage by rectifying and smoothing the voltage induced in the secondary winding;
A switching power supply comprising: an auxiliary power supply that generates a DC auxiliary voltage based on the induced voltage of the auxiliary winding and supplies the auxiliary voltage as a power supply voltage to the active filter control circuit;
The auxiliary power unit is
It is interposed between the auxiliary winding and the active filter control circuit, converts the induced voltage of the auxiliary winding into a direct current to generate a first direct current voltage, and converts the first direct current voltage into the auxiliary voltage. First DC means capable of being supplied to the active filter control circuit as
A second DCing means connected to the auxiliary winding, for converting the induced voltage of the auxiliary winding to DC and boosting the voltage to a second DC voltage that is higher than the first DC voltage;
Constant voltage converting means capable of supplying the second direct current voltage to the active filter control circuit while limiting the predetermined direct current voltage so as not to exceed a preset voltage;
With
When the induced voltage of the auxiliary winding increases as the output voltage of the active filter increases, the voltage is supplied from the constant voltage converting means to the active filter control circuit prior to the voltage supply from the first direct current converting means. After the supply, when the first DC voltage exceeds the output voltage from the constant voltage unit, the operation of the constant voltage unit is stopped and the active filter control circuit is switched from the first DC unit. A switching power supply characterized by supplying a voltage to the power supply. The second direct current means includes a diode having an anode connected to an interconnection end where the auxiliary winding and the primary winding are mutually connected among both ends of the auxiliary winding, and a cathode of the diode One end is connected, and the other end has a capacitor connected to a non-interconnect end different from the interconnect end of both ends of the auxiliary winding,
2. The switching power supply device according to claim 1, wherein a cathode of the diode is connected to the constant voltage means.   The first direct current converting means has an anode connected to a non-interconnection end where the auxiliary winding and the primary winding are connected to each other among both ends of the auxiliary winding, and a cathode connected to the active filter control circuit 3. The switching power supply device according to claim 1, further comprising a diode connected to the switching power supply.   The switching power supply according to claim 1, wherein the predetermined voltage is set by a breakdown voltage of a Zener diode.

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