KR20160132661A - Power supply which cancels noise generated by clamp circuit - Google Patents

Abstract

Provided is a clamp circuit of a switching power supply device comprising: a first voltage input terminal; a second voltage input terminal; a switching element; and a magnetic energy transferring element including an input wire to which a flow of current and a transfer of magnetic energy are interrupted by switching operation of the switching element, a reverse wire having a potential variation with a polarity opposite to that of a potential variation of the input wire, and an output wire magnetically coupled to the input wire to input/output energy. The clamp circuit of the switching power supply device includes: a rectifier for rectifying a counter electromotive force of the input wire of the magnetic energy transferring element; a smoothing capacitor for smoothing a voltage rectified by the rectifier; and a discharge resistance for discharging a charge voltage of the capacitor. One side terminal of the smoothing capacitor is connected to one terminal of the rectifier, and the other side terminal of the smoothing capacitor is connected to an electrical ground via the reverse wire, thus limiting a peak of the counter electromotive force generated by the energy accumulated in a leakage inductance of the input wire of the magnetic energy transferring element. An effect exerted to the outside due to a noise voltage generated in the input wire by the current flowing through the rectifier, and an effect exerted to the outside due to a noise voltage generated in the reverse wire by the current flowing to the reverse wire via the smoothing capacitor have the opposite polarities and thus are canceled each other. Accordingly, generation of EMI is reduced.

Description

[0001] The present invention relates to a power supply which cancels noise generated by a clamp circuit,

The present invention relates to a power supply device capable of canceling noise generated by a clamp circuit to suppress generation of EMI through an input line and an output line, thereby providing a large EMI margin while lowering the cost of the EMI filter.

A clamp circuit is used to limit the peak value of the counter electromotive force generated by the energy accumulated in the leakage inductance of the transformer in the conventional power supply device. The clamp circuit generated a large noise, which was one of the main factors that increased the cost of the EMI filter of the power supply or lowered EMI margins by reducing the EMI of the power supply.

The conventional technique will be briefly described as follows.

Fig. 1 shows a flyback converter having a conventional clamp circuit 21. Fig.

In all of the drawings below, the black dots on each winding of the transformer indicate the beginning or end of the winding.

In Fig. 1, the AC input voltage is rectified and smoothed by the capacitor 11. The control unit 16 controls switching of the switching device 12 in response to the feedback of the output voltage. Energy is accumulated and discharged in the input winding 131 of the transformer 13 by opening and closing the switching element 12 and the output rectifier 14 and the capacitor 15 rectify the voltage of the output winding 133, As shown in FIG.

A part of the magnetic energy stored in the input winding 131 of the transformer 13 does not couple with the output winding 133. [ The energy by the magnetic flux that is not coupled to the output winding 133 when the switching element 12 is cut off discharges the capacitor 19 through the diode 18 for a short time. The capacitor 19 is gradually discharged through the resistor 20 until it is recharged by the energy by the magnetic flux which is not coupled to the output winding 133 when the switching element 12 is cut off in the next period, I'm going back.

The diode 18 used in the clamp circuit 21 composed of the diode 18, the capacitor 19 and the resistor 20 generates a noise current having a high changing speed and a large amplitude at the time of clamping, 131 to generate a large noise voltage. The noise voltage generated in the input winding 131 is transmitted to the input line 22 and also to the output line 23 through the output winding 133 to generate a large EMI to increase the cost of the EMI filter of the power supply. Or low EMI margin.

The conventional technology has a disadvantage in that a large noise voltage is generated in the input winding of the transformer due to the switching characteristic of the clamp circuit, thereby increasing the EMI filter of the power supply device or lowering the EMI margin. The present invention addresses all of these shortcomings of the prior art.

Although the present invention is applied to all switching power supplies, the description according to the embodiments will mainly be described with respect to the flyback converter.

A first voltage input terminal for achieving the above-mentioned object; A second voltage input terminal; A switching element; An input winding to which a current flow and a transfer of magnetic energy are interrupted by a switching operation of the switching element; a reverse winding having a variation in potential of a reverse polarity and a potential variation of the input winding; A clamp circuit of a switching power supply device including a magnetic energy transfer element including an output winding that couples the power supply and draws energy,

A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element; A smoothing capacitor for smoothing the voltage rectified by the rectifier; And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-

An influence exerted on the outside by a noise voltage generated in the input winding due to a current flowing through the rectifier, and an influence externally on a noise voltage generated in the reverse winding by a current flowing through the smoothing capacitor through the reverse winding Are opposite to each other and cancel each other, so that the generation of EMI is lowered.

Further, a switching power supply device including a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor, and an output line for attaining the above-

A ferrite core; An input winding wound around the ferrite core and interrupted by the switching operation of the switching element for current flow and magnetic energy transmission; And a reverse winding wound around the ferrite core, the reverse winding having a variation in potential of the input winding and a variation in potential of a reverse polarity;

A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element;

A smoothing capacitor for smoothing the voltage rectified by the rectifier;

And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-

An influence exerted on the outside by a noise voltage generated in the input winding due to a current flowing through the rectifier, and an influence externally on a noise voltage generated in the reverse winding by a current flowing through the smoothing capacitor through the reverse winding Are opposite to each other and cancel each other, so that the generation of EMI is lowered.

Further, a switching power supply device including a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor, and an output line for attaining the above-

A ferrite core; An input winding wound around the ferrite core and interrupted by the switching operation of the switching element for current flow and magnetic energy transmission; A reverse winding wound around the ferrite core and having a variation of a potential of the input winding and a variation of a potential of a reverse polarity; A magnetic energy transfer element including an output winding magnetically coupled with the input winding to draw energy;

A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element;

A smoothing capacitor for smoothing the voltage rectified by the rectifier;

And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-

The output voltage of the smoothing capacitor is controlled by the noise voltage generated in the input winding by the current flowing through the rectifier and the noise voltage generated in the reverse winding by the current flowing to the reverse winding through the smoothing capacitor, The effects on the line are opposite to each other and cancel each other, so that the generation of EMI is lowered.

Further, a switching power supply device including a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor, and an output line for attaining the above-

A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; And a second switching element connected between the second voltage input terminal and the other terminal of the switching element wound around the ferrite core and being controlled by the switching operation of the switching element, A magnetic energy transfer element including an input winding;

A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;

A smoothing capacitor for smoothing the voltage rectified by the rectifier;

And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,

A noise voltage generated in the first input winding due to a current flowing through the rectifier and a noise voltage generated in the second input winding due to a current flowing through the smoothing capacitor to the second input winding, The influence externally applied to the electrodes is opposite to each other and offset, thereby reducing the generation of EMI.

Further, a switching power supply device including a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor, and an output line for attaining the above-

A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; A second input which is wound on the ferrite core and is connected between the second voltage input terminal and the other terminal of the switching element so that the flow of current and the transmission of magnetic energy are interrupted by the switching operation of the switching element Winding; A magnetic energy transfer element including an output winding magnetically coupled to the first input winding and the second input winding to draw energy;

A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;

A smoothing capacitor for smoothing the voltage rectified by the rectifier;

And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,

And a smoothing capacitor that is generated in the second input winding by the influence of the noise voltage generated in the first input winding by the current flowing through the rectifier to the output line and the current flowing through the smoothing capacitor to the second input winding The effects of the noise voltage on the output line are opposite in polarity to each other, so that the generation of EMI is lowered.

Further, a switching power supply device including a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor, and an output line for attaining the above-

A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; A second input which is wound on the ferrite core and is connected between the second voltage input terminal and the other terminal of the switching element so that the flow of current and the transmission of magnetic energy are interrupted by the switching operation of the switching element Winding; A first output winding magnetically coupled to the first input winding and the second input winding to draw energy; And a second output winding magnetically coupled to the first input winding and the second input winding to draw energy;

A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;

A smoothing capacitor for smoothing the voltage rectified by the rectifier;

And a discharging resistor for discharging the charging voltage of the capacitor,

One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,

And a smoothing capacitor that is generated in the second input winding by the influence of the noise voltage generated in the first input winding by the current flowing through the rectifier to the output line and the current flowing through the smoothing capacitor to the second input winding The effects of the noise voltage on the output line are opposite in polarity to each other, so that the generation of EMI is lowered.

Also provided is a manufactured article comprising the above-described power supply device according to the present invention.

Hereinafter, a power supply device for reducing EMI by canceling noise generated by a clamp circuit according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It is an object of the present invention to reduce the EMI caused by the noise voltage generated in the input winding of the transformer by reducing the EMI and lower the cost of the EMI filter of the power supply or increase the margin of the EMI even when the noise current flows through the clamp circuit Respectively.

1 is a configuration diagram of a flyback converter having a clamp circuit according to the related art.
Fig. 2 is an embodiment of a flyback converter for canceling the influence of a clamp circuit according to the present invention. Fig.
Figure 3 is a cross-sectional view of the transformer of Figure 2
Figures 4 and 5 show further embodiments of a flyback converter for canceling the effects of the clamp circuit according to the present invention.
Figures 6 to 9 illustrate embodiments of the transformer of Figure 4
Figure 10 is a cross-sectional view of the transformer of Figure 5

Fig. 2 shows an embodiment of a flyback converter for canceling the influence of the clamp circuit according to the present invention.

2, the transformer 24 includes a reverse winding 242 having a variation of the potential of the input winding 241 and the input winding 241 and a variation of the potential of the opposite polarity, and the reverse winding 242 of the clamp circuit 28 1 smoothing capacitor 26a is connected between one terminal of the rectifier 25 and the electrical ground and the second smoothing capacitor 26b of the clamp circuit 28 is connected to one terminal of the rectifier 25 and the reverse winding 242, Respectively. Elements other than the transformer 24 and the clamp circuit 28 correspond to Fig.

2, the energy due to the magnetic flux not coupled to the output winding 243 of the magnetic flux generated by the input winding 241 when the switching element 12 is cut off is short-circuited through the rectifier 25 for a short time, The capacitor 26a and the second smoothing capacitor 26b are charged and discharged. The first smoothing capacitor 26a and the second smoothing capacitor 26b are discharged through the resistor 27 and returned to the original voltage until the switching element 12 is recharged when the switching element 12 is turned off in the next period.

A noise current having a fast change speed and a large amplitude generated when the rectifier 25 is clamped flows through the input winding 241 and the reverse winding 242 so that the waveforms of the input winding 241 and the reverse winding 242 Thereby generating the same and opposite polarity noise voltage. The noise voltage generated in the input winding 241 and the noise voltage in the reverse polarity generated in the reverse winding 242 are canceled each other so that the noise potential of the input line 22 is much lower than that in FIG. .

The noise voltage generated by the input winding 241 due to the noise current having a large change speed and large in amplitude generated when the rectifier 25 is clamped and transmitted to the output line 23 through the output winding 243, Polarity noise voltage generated in the reverse winding 242 by the current and transmitted to the output line 23 through the output winding 243 so that the noise potential of the output line 23 is much lower than that in FIG. Thereby reducing the occurrence of EMI.

Therefore, it has the advantage of lowering the cost of the EMI filter of the power supply or raising the margin of the EMI.

2, how much of the current flowing through the rectifier 25 flows to the reverse winding 242 can be set by the ratio of the capacitance values of the first smoothing capacitor 26a and the second smoothing capacitor 26b. Although not shown, the first smoothing capacitor 26a may be removed to allow all of the current flowing through the rectifier 25 to flow through the reverse winding 242. Although not shown, the rectifier 25, the first smoothing capacitor 26a, and the second smoothing capacitor 26b of Fig. 2, Figs. 4 and 5 may be connected in series with one or more resistors added. The ground terminal of the reverse winding 242 is connected to the electrical ground of the "+" input voltage or the "-" input voltage.

Figure 3 is an embodiment of the transformer 24 of Figure 2.

The transformer 24 of Figure 3 is connected to the input winding 241 when the rectifier 25 is clamped while blocking the output winding 243 from capacitively coupling with the input winding 241 by the reverse winding 242 The noise generated when the rectifier 25 is clamped by the output winding 23 and the noise generated through the output winding 243 are transmitted to the output line 23 through the output winding 243 and generated by the reverse winding 242 And has a structure for canceling the noise of reverse polarity. The noise voltage generated in the input winding 241 is larger than the voltage generated in the reverse winding 242 but is reduced by the reverse winding 242 to be transmitted to the output winding 243, Can be canceled by the noise of the low reverse polarity generated in the first embodiment. If the noise of the reverse polarity generated by the reverse winding 242 is much larger than the value for canceling and lowering the noise, the ratio of the capacity value of the first smoothing capacitor 26a is increased to reduce the noise current flowing through the reverse winding 242 .

Figure 4 is another embodiment of a flyback converter that offsets the effects of the clamp circuit according to the present invention.

4 shows that the transformer 29 has an input winding divided into a first input winding 291 and a second input winding 292 and the elements except for the transformer 29 correspond to FIG.

4, when the switching element 12 is cut off, the energy of the magnetic flux generated by the first input winding 291 and the second input winding 292, which is not coupled to the output winding 293, The first smoothing capacitor 26a and the second smoothing capacitor 26b are charged and discharged through the rectifier 25 for a period of time.

The noise current generated by the rectifier 25 flows through the first input winding 291 and the second input winding 292 and flows through the first input winding 291 and the second input 292. In the case where the first smoothing capacitor 26a is absent, The waveform on the winding 292 produces the same and opposite polarity noise voltage. The noise voltage generated in the first input winding 291 and the noise voltage in the opposite polarity generated in the second input winding 292 cancel each other to make the noise potential of the input line 22 much lower than in FIG. .

The noise voltage generated in the first input winding 291 and transmitted to the output line 23 through the output winding 293 is generated in the second input winding 292 and output through the output line 293 23, so that the noise potential of the output line 23 is much lower than that of FIG. 1, thereby lowering the generation of EMI.

Therefore, it has the advantage of lowering the cost of the EMI filter of the power supply or raising the margin of the EMI.

The capacitance value of the first smoothing capacitor 26a can be selected in order to adjust the magnitude of the noise generated in the second input winding 292 to a magnitude necessary for canceling the noise potential of the output line 23 to a minimum. The larger the capacitance value of the first smoothing capacitor 26a is, the less the noise current flowing through the second smoothing capacitor 26b and flowing to the second input winding 292 among the noise currents generated by the rectifier 25 is. Therefore, the ratio of the capacitance value of the first smoothing capacitor 26a and the capacitance value of the second smoothing capacitor 26b can be adjusted to set the optimal offset.

Depending on the design, the first smoothing capacitor 26a may be removed and all of the current flowing through the rectifier 25 may flow through the second input winding 292.

Figure 5 is another embodiment of a flyback converter that offsets the effects of a clamp circuit in accordance with the present invention.

5, the transformer 30 includes an input winding divided into a first input winding 301 and a second input winding 302, an output divided into a first output winding 303 and a second output winding 304 Have a winding. Elements other than the transformer 30 correspond to Fig.

The noise voltage generated in the first input winding 301 by the noise current by the rectifier 25 and transmitted to the output line 23 through the first output winding 303 is input to the second input winding 302, Polarity noise voltage generated by the second output winding 303 and transmitted to the output line 23 so that the noise potential of the output line 23 is much lower than that of FIG. Lower.

Figures 6-9 show embodiments of the transformer of Figure 4.

The first input winding 291 and the second input winding 292 generate noise potentials of opposite polarities due to the noise current generated by the rectifier 25 of the transformer 29a of Fig. And the noise of the opposite polarity transmitted to the output line 23 is canceled. The coupling winding 294 is connected to the output winding 293 while preventing the output winding 293 from being capacitively coupled to the first input winding 291 and the second input winding 292, And has a number of turns that causes capacitive coupling due to the potential difference to be small. Coupling winding 294 is used to lower conductive EMI and is a well known technique.

The transformer 29b of FIG. 7 allows the capacitive coupling due to the potential difference to be generated by the second input winding 292 to be small by the output winding 293, and also by the noise current generated by the rectifier 25, The noise generated in the input winding 291 and transmitted to the output line 23 through the output winding 293 and the noise generated in the second input winding 292 and transmitted to the output line 23 through the output winding 293 And has a structure for canceling the noise of reverse polarity. 7, the noise voltage generated in the first input winding 291 by the noise current generated by the rectifier 25 is larger than the voltage generated in the second input winding 292. [ However, since the noise voltage generated by the first input winding 291 is cut off by the second input winding 292 and transferred to the output winding 293, the low voltage generated by the second input winding 292 It can be canceled by the noise of polarity.

When the number of turns of the second input winding 292 and the number of turns of the output winding 293 are different in the transformer 29b of Fig. 7, capacitive coupling by the potential difference between the second input winding 292 and the output winding 293 . 8 shows the coupling winding 294 between the second input winding 292 and the output winding 293 so that the output winding 293 generates less capacitive coupling in such a case.

9 has a structure in which the first input winding 291 and the second input winding 292 are positioned in parallel with the winding layer facing the output winding 293. [

FIG. 10 shows an embodiment of the transformer 30 of FIG.

The transformer 30 of FIG. 10 generates noise voltages symmetrically opposite in polarity in the first input winding 301 and the second input winding 302 due to the noise current generated by the rectifier 25, To the second output winding (303) and the second output winding (304) to be canceled by the output capacitor (15).

Therefore, the EMI through the input line 22 and the output line 23 is much lower than in Fig.

10, the capacitive coupling by the potential difference between the first input winding 301 and the first output winding 303 and the capacitive coupling by the potential difference between the second input winding 302 and the second output winding 303 The capacitive coupling is canceled to provide low conduction EMI. A first coupling winding and a second coupling winding are provided between the first input winding 301 and the first output winding 303 and between the second input winding 302 and the second output winding 303 for lower conduction EMI, May be added.

While the present invention has been described in connection with the accompanying drawings, it is to be understood that the invention is not limited to the preferred embodiments. It is also possible to insert an insulating tape between the windings of the transformer, not shown in the present invention, or to add additional output windings for drawing additional second or third output voltages required by the power supply, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the present invention.

11 is an input capacitor, 12 is a switching element, 13 is a conventional transformer, 14 is an output rectifier, 15 is an output capacitor, 16 is a control unit, 18 is a diode, 19 is a capacitor, 20 is a resistor, 21 is a clamp circuit, 23 is an output line, 24 is a transformer, 25 is a diode, 26 is a capacitor, 27 is a resistor, 28 is a clamp circuit, 29 and 30 are transformers

Claims (13)

A first voltage input terminal; A second voltage input terminal; A switching element; An input winding to which a current flow and a transfer of magnetic energy are interrupted by a switching operation of the switching element; a reverse winding having a variation in potential of a reverse polarity and a potential variation of the input winding; A clamp circuit of a switching power supply device including a magnetic energy transfer element including an output winding that couples inductively and draws energy,
A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-
An influence exerted on the outside by a noise voltage generated in the input winding due to a current flowing through the rectifier, and an influence externally on a noise voltage generated in the reverse winding by a current flowing through the smoothing capacitor through the reverse winding Are opposite to each other and cancel each other out so that the generation of EMI is lowered. The clamp circuit of the switching power supply according to claim 1, further comprising a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, The ratio of the current flowing to the reverse winding among the current flowing through the rectifier is set according to the setting of the ratio of the capacity value of the two smoothing capacitors. 1. A switching power supply device comprising a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor and an output line,
A ferrite core; An input winding wound around the ferrite core and interrupted by the switching operation of the switching element for current flow and magnetic energy transmission; And a reverse winding wound around the ferrite core, the reverse winding having a variation in potential of the input winding and a variation in potential of a reverse polarity;
A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-
An influence exerted on the outside by a noise voltage generated in the input winding due to a current flowing through the rectifier, and an influence externally on a noise voltage generated in the reverse winding by a current flowing through the smoothing capacitor through the reverse winding Are opposite to each other and cancel each other to reduce EMI generation. The switching power supply device according to claim 3, further comprising a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, wherein the smoothing capacitor, the second smoothing capacitor The ratio of the current flowing through the rectifier to the reverse winding is set according to the setting of the ratio of the capacity value of the rectifier to the capacity of the rectifier. 1. A switching power supply device comprising a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor and an output line,
A ferrite core; An input winding wound around the ferrite core and interrupted by the switching operation of the switching element for current flow and magnetic energy transmission; A reverse winding wound around the ferrite core and having a variation of a potential of the input winding and a variation of a potential of a reverse polarity; A magnetic energy transfer element including an output winding magnetically coupled with the input winding to draw energy;
A rectifier for rectifying a counter electromotive force of the input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the reverse winding so that the energy accumulated in the leakage inductance of the input winding of the magnetic energy transfer device Limit the peak value of the counter electromotive force generated by the voltage-
The output voltage of the smoothing capacitor is controlled by the noise voltage generated in the input winding by the current flowing through the rectifier and the noise voltage generated in the reverse winding by the current flowing to the reverse winding through the smoothing capacitor, And the EMI is less likely to be canceled due to the opposite polarity of the influence on the line. The switching power supply according to claim 4, further comprising: a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, and the smoothing capacitor, the second smoothing capacitor The ratio of the current flowing through the rectifier to the reverse winding is set according to the setting of the ratio of the capacity value of the rectifier to the capacity of the rectifier. 1. A switching power supply device comprising a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor and an output line,
A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; And a second switching element connected between the second voltage input terminal and the other terminal of the switching element wound around the ferrite core and being controlled by the switching operation of the switching element, A magnetic energy transfer element including an input winding;
A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,
A noise voltage generated in the first input winding due to a current flowing through the rectifier and a noise voltage generated in the second input winding due to a current flowing through the smoothing capacitor to the second input winding, So that the generation of EMI is lowered. ≪ RTI ID = 0.0 > [0002] < / RTI > The switching power supply device according to claim 7, further comprising a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, and the smoothing capacitor, the second smoothing capacitor The ratio of the current flowing through the rectifier to the second input winding is set according to the setting of the ratio of the capacity value of the rectifier to the capacity of the rectifier. 1. A switching power supply device comprising a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor and an output line,
A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; A second input which is wound on the ferrite core and is connected between the second voltage input terminal and the other terminal of the switching element so that the flow of current and the transmission of magnetic energy are interrupted by the switching operation of the switching element Winding; A magnetic energy transfer element including an output winding magnetically coupled to the first input winding and the second input winding to draw energy;
A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,
And a smoothing capacitor that is generated in the second input winding by the influence of the noise voltage generated in the first input winding by the current flowing through the rectifier to the output line and the current flowing through the smoothing capacitor to the second input winding And the influence of the noise voltage on the output line is opposite to that of the output line, so that the generation of EMI is reduced. The switching power supply device according to claim 9, further comprising a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, wherein the smoothing capacitor and the second smoothing capacitor The ratio of the current flowing through the rectifier to the second input winding is set according to the setting of the ratio of the capacity value of the rectifier to the capacity of the rectifier. 1. A switching power supply device comprising a first voltage input terminal, a second voltage input terminal, a switching element, an output rectifier, an output smoothing capacitor and an output line,
A ferrite core; A first input winding wound around the ferrite core and connected between the first voltage input terminal and one terminal of the switching element so that current flow and magnetic energy transmission are interrupted by the switching operation of the switching element, and; A second input which is wound on the ferrite core and is connected between the second voltage input terminal and the other terminal of the switching element so that the flow of current and the transmission of magnetic energy are interrupted by the switching operation of the switching element Winding; A first output winding magnetically coupled to the first input winding and the second input winding to draw energy; And a second output winding magnetically coupled to the first input winding and the second input winding to draw energy;
A rectifier for rectifying the counter electromotive force of the first input winding and the second input winding of the magnetic energy transfer element;
A smoothing capacitor for smoothing the voltage rectified by the rectifier;
And a discharging resistor for discharging the charging voltage of the capacitor,
One terminal of the smoothing capacitor is connected to one terminal of the rectifier and the other terminal of the smoothing capacitor is connected to the electric ground through the second input winding so that the first input winding of the magnetic energy transfer element and the first input winding of the magnetic energy transfer element, Limit the peak value of the back electromotive force generated by the energy accumulated in the leakage inductance of the two-input winding,
And a smoothing capacitor that is generated in the second input winding by the influence of the noise voltage generated in the first input winding by the current flowing through the rectifier to the output line and the current flowing through the smoothing capacitor to the second input winding And the influence of the noise voltage on the output line is opposite to that of the output line, so that the generation of EMI is reduced. The switching power supply apparatus according to claim 11, further comprising a second smoothing capacitor connected between one terminal of the rectifier connected to one terminal of the smoothing capacitor and an electrical ground, and the smoothing capacitor, the second smoothing capacitor The ratio of the current flowing through the rectifier to the second input winding is set according to the setting of the ratio of the capacity value of the rectifier to the capacity of the rectifier. A manufactured article characterized by comprising a switching power supply device according to any one of claims 3 to 12.

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