KR20160123581A - Transformer and power supply for cancelling noise generated by lines and windings - Google Patents

Abstract

A switching-type power supply of the present invention comprises: a first-side smoothing capacitor which smooths an input current at one side of the power supply to supply a voltage; a second-side smoothing capacitor which smooths an input current at the opposite side of the power supply to supply a voltage; a first coupling unit at the one side of the power supply, coupled to the opposite side of the power supply; a second coupling unit at the one side of the power supply, coupled to the opposite side of the power supply; and a third coupling unit at the opposite side of the power supply, coupled to a terminal of the second-side smoothing capacitor by being capacitively coupled to the first and second coupling units. A noise, which is generated between one terminal of the first-side smoothing capacitor at the one side of the power supply and the first coupling unit and transferred to the third coupling unit at the opposite side of the power supply via the first coupling unit, and a noise, which is generated between the other terminal of the first-side smoothing capacitor at the one side of the power supply and the second coupling unit and transferred to the third coupling unit at the opposite side of the power supply via the second coupling unit, are cancelled each other. Therefore, EMI is reduced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic energy transfer device and a power supply device for canceling noise generated in a line and a winding,

[0001] The present invention relates to a magnetic energy transfer device and a power supply device, and more particularly to a magnetic energy transfer device and a power supply device which generate noise in a line between an input capacitor and a transformer of a power supply device, cancel noise transmitted to a secondary side, To a magnetic energy transfer device and a power supply device that cancel out noise transmitted through the output windings of the transformer and cancel noise transmitted to the primary side to provide low radiation EMI. The present invention also relates to a magnetic energy transfer device and a power supply device which provide low conduction EMI by canceling the potential of noise generated by capacitive coupling of the potential of the primary side of the transformer to the output winding.

In a general switching type power supply apparatus, noise potential generated in a line between an input smoothing capacitor and a transformer when switching is transferred to an output line through a transformer to generate high EMI.

Further, the noise current of the high frequency component flows due to the ringing characteristic of the output rectifier connected to the output winding, so that a large noise potential is generated between the entire output winding of the transformer and the line between the output smoothing capacitor and the output winding terminal. This noise potential is transmitted to the input line through the transformer to generate high EMI.

The conventional technique will be briefly described as follows.

Figure 1 shows a prior art flyback converter.

In all of the drawings presented below, the black color shown on each winding of the transformer indicates the beginning or end of the winding.

In FIG. 1, the AC input voltage is rectified and smoothed by the input smoothing capacitor 11. The switching element 12 is interrupted in response to the feedback of the output voltage so that the accumulation and emission of the energy takes place in the input winding 131 of the transformer 13 and the output rectifier 14 and the output smoothing capacitor 15 are connected to the output winding 132 to rectify the voltage to supply power to the load. The coupling winding 133 is filled with a gap between the input winding 131 and the output winding 132 and wound to cut off the capacitive coupling from the input winding 131 to the output winding 132. The capacitive coupling between the input winding 131 and the output winding 132 generated in spite of the cutoff of the coupling winding 133 is changed by the difference in the number of turn (T) between the coupling winding 133 and the output winding 132 Thereby reversing the polarity of the capacitive coupling. Thus, even if the potential of the input winding 131 fluctuates, the potential of the output line is prevented from fluctuating, thereby lowering the conduction EMI.

1, one terminal of the coupling winding 133 on the primary side of the transformer 13 is connected to one side of the input smoothing capacitor 11 through a line 16 having a long length and a large switching current flowing therethrough, Terminal. The terminal of the coupling winding 133 connected to one terminal of the input smoothing capacitor 11 has a noise potential which is lowered in the line 16 and the coupling winding 133 faces the output winding 132 and is capacitively coupled The large noise potential dropped by the line 16 is transmitted to the output winding 132 through the coupling winding 133. [

On the secondary side of the transformer 13, a noise current having a high frequency component of several tens MHz or more flows through the output winding 132 of the transformer by the ringing characteristic of the output rectifier 14, A noise potential is generated. Further, the noise current of the output rectifier 14 lowers the large noise potential to the line 17 between the output winding 132 and the output smoothing capacitor 15. The large noise potential generated in the whole of the line 17 and the output winding 132 is transferred to the input line by the capacitive coupling of the output winding 132 and the coupling winding 133.

Therefore, a large noise potential difference is generated between one terminal of the input smoothing capacitor 11 and one terminal of the output smoothing capacitor 15, thereby generating a high EMI through the input line 18 and the output line 19 .

In addition, in the prior art, an expensive filter is mounted on the input and output terminals of the power supply device in order to lower the influence of the noise potential dropped on the line 16 and the line 17 and the noise generated in the entire output winding 132 of the transformer. It has the disadvantage that the cost increases and becomes larger.

In the conventional technique, the noise voltage on the primary side generated in the line in which the large current of the switching element flows is transmitted to the secondary side through the windings of the transformer, and by the large ringing current of the high frequency component generated by the output rectifier, The noise voltage of the secondary side generated at the secondary side is transmitted to the primary side through the windings of the transformer so that the input line and the output line have a large noise potential and generate high radiation EMI. Cost filters must be mounted on the input and output terminals of the power supply unit, which leads to a disadvantage that the cost is increased and the size is increased.

The present invention addresses these shortcomings of the prior art.

In order to achieve the above-mentioned object, a switching-

A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage; A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage; A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; And a third coupling unit capacitively coupled to the first coupling unit and the second coupling unit on the other side of the power supply unit and coupled to one terminal of the other side smoothing capacitor,

A noise generated from one side of the one smoothing capacitor on one side of the power supply device and transmitted to the third coupling part on the other side of the power supply device through the first coupling part generated between the first coupling part, The noise generated between the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the second coupling unit is canceled to lower the EMI.

In order to achieve the above-mentioned object, a switching-

A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage; A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage; A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A third coupling unit capacitively coupled with the first coupling unit at the other side of the power supply unit and coupled to one terminal of the other side smoothing capacitor; And a fourth coupling unit capacitively coupled with the second coupling unit on the other side of the power supply unit and coupled to the other side terminal of the other side smoothing capacitor,

A noise generated between one terminal of the one smoothing capacitor on one side of the power supply unit and the first coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the first coupling unit, Noise generated between the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the fourth coupling unit on the other side of the power supply unit through the second coupling unit is canceled, thereby reducing the EMI.

In order to achieve the above-mentioned object, a switching-

A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage; A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage; A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A third coupling unit coupled to one side of the power supply unit from the other side of the power supply unit; And a fourth coupling unit coupled to one side of the power source unit from the other side of the power source unit,

A noise generated between one terminal of the one smoothing capacitor on one side of the power supply unit and the first coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the first coupling unit, The noise generated between the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the fourth coupling unit on the other side of the power source device through the second coupling unit is offset by symmetry and is opposite in polarity, A noise generated between one terminal of the other smoothing capacitor on the other side of the device and the third coupling unit and transmitted to the first coupling unit on one side of the power source device through the third coupling unit and the noise generated on the other side And a fourth coupling unit which is connected between the other terminal of the smoothing capacitor and the fourth coupling unit, The noise transmitted to the second coupler is canceled and the EMI is lowered.

And a switching power supply unit including an input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control unit, at least one output rectifier, an output smoothing capacitor, and an output line The magnetic energy transfer element used is,

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; An output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A first coupling unit for generating a capacitive coupling at a primary side of the magnetic energy transfer device so as to face the output winding; And a second coupling portion for generating a capacitive coupling at a primary side of the magnetic energy transfer device, the coupling portion facing the output winding,

Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, Connected to a line connecting between the second terminals of the input smoothing capacitor,

And a second coupling unit connected to the first coupling unit and the output winding, wherein the first coupling unit and the output winding are connected to each other by a capacitive coupling between the one end of the first coupling unit and the first terminal of the input smoothing capacitor, Noise component of the magnetic field is shifted from a line between one terminal of the second coupling portion and the second terminal of the input smoothing capacitor and is capacitively coupled between the second coupling portion and the output winding, And the noise component transmitted to the antenna is canceled to lower the EMI.

And a switching power supply unit including an input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control unit, at least one output rectifier, an output smoothing capacitor, and an output line The magnetic energy transfer element used is,

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And a second coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the second output winding,

Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, Connected to a line connecting between the second terminals of the input smoothing capacitor,

And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, And the noise component transmitted to the secondary side of the device is canceled to lower the EMI.

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And a second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy,

One terminal of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and one terminal of the second output winding is connected to the second terminal of the output smoothing capacitor through a connection line Wherein a rectified current having a substantially identical waveform flows through the first output winding and the second output winding,

And a second smoothing capacitor that is lowered by a current flowing in a connection line between one terminal of the first output winding and the first terminal of the smoothing capacitor and is connected to the first output winding through the coupling between the first output winding and the magnetic energy transfer element internal element, A noise component transmitted to a primary side of the transmission element and a current flowing through a connection line between one terminal of the second output winding and the second terminal of the output smoothing capacitor, And the noise component transmitted to the primary side of the magnetic energy transfer device is canceled through coupling with the element inside the device, thereby lowering the EMI.

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And a second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy,

One terminal of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and one terminal of the second output winding is connected to the second terminal of the output smoothing capacitor through a connection line Wherein a rectified current having a substantially identical waveform flows through the first output winding and the second output winding,

A noise component generated in the first output winding by the noise current flowing in the first output winding and transmitted to the primary side of the magnetic energy transfer element through the coupling between the first output winding and the magnetic energy transfer element inner element, And a noise generated in the second output winding by the noise current flowing in the second output winding and transmitted to the primary side of the magnetic energy transfer element through the coupling between the second output winding and the magnetic energy transfer element internal element Components are canceled to lower the EMI.

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And a second coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the second output winding,

Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, One end of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and the other end of the first output winding is connected to the one end of the second output winding, Is connected to the second terminal of the output smoothing capacitor through a connection line, a rectified current having a waveform almost coinciding with the first output winding and the second output winding flows,

And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, The noise component transmitted to the secondary side of the device is canceled,

Wherein the first output winding is lowered by a current flowing in a connection line between one terminal of the first output winding and the first terminal of the output smoothing capacitor and is capacitively coupled between the first coupling portion and the first output winding, The noise component transmitted to the primary side of the transmission element and the current flowing in the connection line between the one terminal of the second output winding and the second terminal of the output smoothing capacitor are lowered by the second coupling portion and the second output And the noise component transmitted to the primary side of the magnetic energy transfer device is canceled by the capacitive coupling between the windings to lower the EMI.

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And a second coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the second output winding,

Wherein one terminal of the first coupling portion is connected to a line connecting between the one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, One end of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and the other end of the first output winding is connected to the one end of the second output winding, Is connected to the second terminal of the output smoothing capacitor through a connection line, a rectified current having a waveform almost coinciding with the first output winding and the second output winding flows,

And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, The noise component transmitted to the secondary side of the device is canceled,

A noise component generated in the first output winding due to a noise current flowing in the first output winding and transmitted to the primary side of the magnetic energy transfer element by capacitive coupling between the first coupling portion and the first output winding, And a noise generated in the second output winding due to a noise current flowing in the second output winding and transferred to the primary side of the magnetic energy transfer element by capacitive coupling between the second coupling portion and the second output winding, Components are canceled to lower the EMI.

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And a coupling part for generating a capacitive coupling by facing the first output winding and the second output winding and having one terminal connected to one terminal of the input smoothing capacitor,

The coupling portion blocking the input winding from capacitively coupling to the first output winding and the second output winding,

The capacitive coupling due to the potential difference of the switching frequency component between the coupling portion and the first output winding and the capacitive coupling due to the potential difference of the switching frequency component between the coupling portion and the second output winding are canceled, .

An input smoothing capacitor having a first terminal and a second terminal for achieving the above object, a switching element, a control section, at least one output rectifier, an output smoothing capacitor having a first terminal and a second terminal, A magnetic energy transfer element used in a switching type power supply device including a line includes:

A core of a magnetic energy transfer element; And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted; A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; A first coupling unit which generates a capacitive coupling with respect to the first output winding and has one terminal connected to one terminal of the input smoothing capacitor; And a second coupling portion that generates a capacitive coupling opposite to the second output winding and has one terminal connected to one terminal of the input smoothing capacitor,

Wherein the first coupling portion blocks the input winding from capacitively coupling with the first output winding and the second coupling portion prevents the input winding from capacitively coupling with the second output winding,

The capacitive coupling due to the potential difference of the switching frequency component between the first coupling portion and the first output winding and the capacitive coupling due to the potential difference of the switching frequency component between the second coupling portion and the second output winding are canceled , And low EMI.

Further, a switching power supply apparatus including the above-described magnetic energy transfer device according to the present invention is provided.

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

Hereinafter, a magnetic energy transfer device and a power supply device for canceling noise generated in a line and a winding according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The present invention is characterized in that the noise voltage generated in the two lines of the primary side of the power supply device between the input smoothing capacitor and the transformer through which the large current of the switching device flows is canceled so as not to be transmitted to the secondary side of the power supply device, The noise voltage generated in the output winding by the large ringing current of the high frequency component generated by the output rectifier and the noise voltage generated in the two lines between the output smoothing capacitor and the transformer are canceled so as not to be transmitted to the primary side of the power supply, The noise potential between the smoothing capacitor and the output smoothing capacitor is drastically lowered, and the radiation EMI is greatly reduced. Thus, the filter is not required to be connected to the input terminal and the output terminal of the power supply device.

1 is a configuration diagram of a flyback converter according to the prior art;
Figures 2 to 5 show the principle of the power supply device according to the invention.
6 is an embodiment of a flyback converter according to the present invention.
Figures 7 and 8 are structural diagrams of an embodiment of the transformer of Figure 6;
9 is another embodiment of a flyback converter according to the present invention.
10 is a structural view of one embodiment of the transformer of FIG.
11 to 13 show another embodiment of the flyback converter according to the present invention.
Figure 14 is a structural view of one embodiment of the transformer of Figure 13;
15 is a further embodiment of a flyback converter according to the present invention.

The present invention applies to all switching power supplies, but mainly describes flyback converters.

2 to 5 are schematic diagrams of a power supply device according to the present invention.

Figs. 2 to 4 are diagrams for explaining a case where the first noise source 102 and the second noise source 103 which generate symmetrical reverse polarity noise on the side of the one smoothing capacitor 101 and the second noise source 103 are used for the other smoothing capacitor 109 side And a power supply device for lowering the EMI generated through the line connected to the other smoothing capacitor 109 by canceling the smoothing capacitor so as to be less transmitted.

2, the one-side smoothing capacitor 101 corresponds to one of the input smoothing capacitor 11 and the output smoothing capacitor 15 in Fig. 1, and the other smoothing capacitor 109 corresponds to the input smoothing capacitor 11 or the output smoothing capacitor 15. [ (15). The first noise source 102 and the second noise source 103 are opposite in polarity to each other and generate a symmetric noise. For example, in FIG. 1, the current flowing in the connection line 16 between one terminal of the input smoothing capacitor 11 and the input winding 131 and the current flowing from the other terminal of the input smoothing capacitor 11 The current flowing in the connection line 20 between the terminals is the same. The noise voltage appearing at the connection point between the input winding 131 and the line 16 is dropped to the connection line 16 between one terminal of the input smoothing capacitor 11 and the input winding 131 and the noise voltage appearing at the connection point between the input smoothing capacitor 11 and the input smoothing capacitor 11 The noise voltage appearing at the connection point between one terminal of the switching element 12 and the line is lowered to the connection line 20 between the one terminal and the one terminal of the switching element 12 so that the noise voltage is almost symmetrical but the polarity is opposite. The noise voltage appearing at the connection point between the input winding 131 and the line 16 dropped to the connection line between one terminal of the input smoothing capacitor 11 and the input winding 131 becomes the noise of the first noise source 102 And is dropped on the connection line between the other terminal of the input smoothing capacitor 11 and one terminal of the switching element 12 so that the noise voltage appearing at the connection point between the one terminal of the switching element 12 and the line becomes the second noise source (103).

The noise of the first noise source 102 and the noise of the second noise source 103 may be either a noise source generating noise at the primary side of the power source device or a noise source generating noise at the secondary side of the power source device.

The noise of the first noise source 102 is transmitted to one terminal of the other side smoothing capacitor 109 by the capacitive coupling between the first coupling portion 104 and the third coupling portion 106 and the noise of the second noise source 103 Is transmitted to the other terminal of the other side smoothing capacitor 109 by capacitive coupling between the second coupling portion 105 and the fourth coupling portion 107. Since the two noises are opposite in polarity and symmetrical Lt; / RTI > Therefore, a noise having a size corresponding to the difference between the noise of the first noise source 102 and the noise of the second noise source 103 appears between the one-side smoothing capacitor 101 and the other side smoothing capacitor 109.

When the noise of the first noise source 102 and the noise of the second noise source 103 are adjusted to be almost equal to each other, noise potential is canceled between the one smoothing capacitor 101 and the other smoothing capacitor 109, The generation of EMI through the line connected to the other smoothing capacitor 109 is greatly reduced.

FIG. 3 is a schematic view showing a state in which the first noise source 102 and the second noise source 103 have the opposite polarity and noise symmetrical to each other through the first and second coupling parts 104 and 105, 108, canceled by the fifth coupling unit 108, and not transmitted to the other side smoothing capacitor 109, thereby lowering the EMI.

4 is a view showing a state where noise that is opposite in polarity and symmetrical to the first noise source 102 and the second noise source 103 is transmitted to the third coupler 104 through the first coupler 104 and the second coupler 105 106 and the fourth coupling unit 107 so as not to be transmitted to the other side smoothing capacitor 109, thereby lowering the EMI.

3 and 4, when the noise of the first noise source 102 and the noise of the second noise source 103 are controlled to be opposite in polarity and almost the same in size, the one-side smoothing capacitor 101 and the other side smoothing capacitor 109, there is an advantage that the radiation EMI through the line connected to the other smoothing capacitor 109 is significantly lowered.

FIG. 5 shows a principle diagram of a power supply device for reducing radiated EMI by canceling symmetrical opposite polarity noise generated by the two sides, thereby preventing transmission to the other side.

In Fig. 5, the first noise source 102 and the second noise source 103 are origins of opposite symmetrical polarities at one side of the power supply device and generate a symmetrical noise. The noise of the first noise source 102 is transmitted to one terminal of the other side smoothing capacitor 109 by the capacitive coupling between the first coupling portion 104 and the third coupling portion 106 and the noise of the second noise source 103 Is transmitted to the other terminal of the other smoothing capacitor 109 by the capacitive coupling between the second coupling portion 105 and the fourth coupling portion 107. Also, the third noise source 110 and the fourth noise source 111 are also sources of opposite polarity and near symmetrical noise on the other side of the power source device. The noise of the third noise source 110 is transmitted to one terminal of the one smoothing capacitor 101 by the capacitive coupling of the third coupling portion 106 and the first coupling portion 104 and the noise of the fourth noise source 111 Is transmitted to the other terminal of the one smoothing capacitor 101 by capacitive coupling between the fourth coupling portion 107 and the second coupling portion 105.

5, a value due to the difference between the noise of the first noise source 102 and the noise of the second noise source 103 appears in the other side smoothing capacitor 109, A value due to the difference between the noise of the first noise source 111 and the noise of the second noise source 111 appears. The noise of the first noise source 102 and the noise of the second noise source 103 are adjusted to be nearly equal in magnitude with the opposite polarity close to the symmetry and the noise of the third noise source 110 and the noise of the fourth noise source 111, Noise between the first smoothing capacitor 101 and the second smoothing capacitor 109 and the noise of the first noise source 102 and the second noise source 103 between the one smoothing capacitor 101 and the other smoothing capacitor 109, The noise of the third noise source 110 and the noise of the fourth noise source 111 hardly appear. Therefore, the radiation EMI through the line connected to the smoothing capacitor 101 and the smoothing capacitor 109 is significantly lowered.

The noise of the first noise source 102 and the noise of the second noise source 103 in FIG. 5 may be noise generating noise in the primary side of the power supply device, and the noise of the third noise source 110 and the noise of the third The noise of the noise source 111 may be a noise that generates noise at the secondary side of the power source device.

2 to 5, the first coupling portion 104, the second coupling portion 105, the third coupling portion 106, the fourth coupling portion 107, and the fifth coupling portion 108 are connected to each other, As shown in FIG. Also, the first coupling portion 104 and the third coupling portion 106 may be constituted by one capacitor, and the second coupling portion 105 and the fourth coupling portion 107 may be constituted by one capacitor.

6 is an embodiment of a flyback converter according to the present invention.

6 is a power supply device having a structure for lowering EMI by canceling the noise generated in the lines 16 and 20 on the primary side so as to be transmitted to the secondary side less.

In Fig. 6, the elements except for the transformer 22 correspond to the elements of Fig.

In FIG. 6, the AC input voltage is rectified and smoothed by the input smoothing capacitor 11. The switching element 12 is interrupted in response to the feedback of the output voltage so that the accumulation and emission of energy take place in the input winding 221 of the transformer 22 and the output rectifier 14 and the output smoothing capacitor 15 are connected to the output winding 223 are rectified to supply power to the load. The first coupling portion 224 having one terminal connected to one terminal of the input smoothing capacitor 11 through the line 16 is capacitively coupled to the output winding 223. The second coupling portion 225 whose one terminal is connected to the other terminal of the input smoothing capacitor 11 through the line 20 through which the switching current of the switching element 12 flows is also capacitively coupled to the output winding 223 do.

The first coupling portion 224 and the second coupling portion 225 may be formed of a coil or a shield plate.

In Fig. 6, the current flowing through the line 16 having a longer length and the current flowing through the line 20 having a longer length are the same in waveform and the opposite in direction when the switching element 12 is switched. Therefore, the noise voltage at the connection point between the line 16 and one terminal of the first coupling unit 224 with reference to one terminal of the input smoothing capacitor 11 and the noise voltage at the other terminal of the input smoothing capacitor 11 The noise voltage at the connection point of one terminal of the line 20 and the second coupling portion 225 has a waveform whose polarity is opposite and almost symmetrical.

The noise voltage at the connection point between the line 16 on one side of the input smoothing capacitor 11 and one terminal of the first coupling unit 224 is transmitted to the output winding 223 through the first coupling unit 224 And the noise voltage at the connection point between the line 20 and one terminal of the second coupling part 225 with respect to the other terminal of the input smoothing capacitor 11 is output through the output coupling line 223 ).

If the noise voltage of one terminal of the first coupling portion 224 and the noise voltage of the one terminal of the second coupling portion 225 are adjusted to be almost the same, the two noises transmitted to the output winding 223 are opposite polarities, The voltage of the noise component generated in the line 16 and the line 20 does not appear on the secondary side and the radiation EMI through the output line 19 is significantly lower than that in FIG.

The noise voltage of one terminal of the first coupler 224 and the noise voltage of the terminal of the second coupler 225 can be adjusted by controlling the lengths and thicknesses of the lines 16 and 20 and the positions of the connection points, You can fit it.

The noise voltage generated in the line 16 and the line 20 is canceled between the terminal of the input smoothing capacitor 11 and the terminal of the smoothing capacitor 15 and the potential difference due to the remaining difference But has the advantage that the radiation EMI is also lowered as compared with Fig.

Figs. 7 and 8 show an embodiment of the transformer of Fig. 6, in which the first coupling portion 224 and the second coupling portion 225 are windings.

7 has an input winding 221 at the lower end of the bobbin 227 and an output winding 223 for magnetically coupling to the input winding 221. The output winding 223 is connected to one side of the output winding 223, The first coupling portion 224 is located such that the second coupling portion 225 is capacitively coupled and capacitively coupled to the other surface of the output winding 223. [ The first coupling portion 224 and the second coupling portion 225 transfer the noise voltage of the same waveform having the same polarity and opposite polarity to the output winding 223 to cancel the transmission of noise to the secondary side.

7, when the noise voltage at the connection point of one terminal of the line 16 and the first connection unit 224 is larger than the noise voltage of the connection point of the line 20 and one terminal of the second connection unit 225, The number of turns of the first coupling portion 224 is made smaller than the number of turns of the second coupling portion 225 so that the capacitive coupling between the first coupling portion 224 and the output winding 223 is generated only in a partial area The sum of the noise transmitted from the first coupling portion 224 and the second coupling portion 225 to the output winding 223 can be made close to zero.

If the noise voltage at the connection point of one terminal of the line 20 and the second connection unit 225 is larger than the noise voltage of the connection point of the line 16 and one terminal of the first connection unit 224, The first engaging portion 224 and the second engaging portion 225 are exchanged with each other and the number of turns of the second engaging portion 225 is made smaller than the number of turns of the first engaging portion 224, The sum of the noise transmitted from the first coupling portion 224 and the second coupling portion 225 to the output winding 223 becomes smaller than the sum of the noise generated from the first coupling portion 224 and the second coupling portion 225 Zero can be set close to.

The transformer of FIG. 8 has the input winding 221 at the lower end of the bobbin 227 and the first output winding 223a and the second output winding 223b are positioned so as to be magnetically coupled to the input winding 221 The first coupling portion 224 is located on the winding surface between the first output winding 223a and the input winding 221 so as to be capacitively coupled with the first output winding 223a and the second output winding 223b, And the second coupling portion 225 is positioned on the winding surface between the second output winding 223b and the input winding 221 so as to be capacitively coupled.

The noise voltage transmitted by the first coupling section 224 to the first output winding 223a and the noise voltage transmitted from the second coupling section 225 to the second output winding 223b are opposite in polarity to each other, Are equal to each other.

8, when the noise voltage at the connection point of one terminal of the line 16 and the first connection unit 224 is lower than the noise voltage of the connection point of the line 20 and one terminal of the second connection unit 225, An additional coupling winding connected to the line having the noise potential is coupled to the other winding surface of the first output winding 223a or the second output winding 223b so that the first output winding 223a and the second output winding 223b may be close to zero.

9 is another embodiment of a flyback converter according to the present invention.

9 is a graph showing the relationship between the noise generated in the secondary lines 17 and 25 and the noise generated in the secondary windings in the primary side To lower the EMI so as to reduce the EMI.

In Fig. 9, the elements except for the transformer 23 and the output rectifier 24 correspond to the elements in Fig.

9, the output rectifier 24 and the output smoothing capacitor 15 rectify the voltages of the first output winding 232 and the second output winding 233, which are coupled with the input winding 231 to draw magnetic energy And supplies power to the load.

The input winding 231 of the transformer 23, the first coupling portion 234 and the second coupling portion 235 are connected to the input winding 221 of the transformer 22 of FIG. 6, the first coupling portion 224, 2 coupling portion 225, respectively.

The first coupling portion 234 and the second coupling portion 235 may be formed of a coil or a shield plate.

The first coupling portion 234 and the first output winding 232 are capacitively coupled to transmit noise potentials to each other while the second coupling portion 235 and the second output winding 233 are capacitively coupled And transmits the noise potential of each other.

That is, the noise voltage at the connection point between the line 16 based on one terminal of the input smoothing capacitor 11 and one terminal of the first coupling unit 234 is supplied to the first output winding 232 and the noise voltage at the connection point between the line 20 and the second coupling part 235 with reference to the other terminal of the input smoothing capacitor 11 is transmitted through the second coupling part 235 And is transmitted to the second output winding 233. The noise voltage delivered to the first output winding 232 and the second output winding 233 is canceled by the output smoothing capacitor 15 so that the line 16 is connected to the secondary side of the power supply, The voltage of the noise component generated in the line 20 does not appear.

The noise voltage generated in the first output winding 232 and the noise voltage generated in the line 25 between the output smoothing capacitor 15 and the first output winding 232 due to the high ringing current of the high frequency component generated by the output rectifier 24 Is transmitted to the first coupling portion 234 through the first output winding 232 and the noise voltage generated in the second output winding 233 and the noise voltage generated in the output smoothing capacitor 15 and the second output The noise voltage generated in the line 17 between the windings 233 is transmitted to the second coupling portion 235 through the second output winding 233.

The sum of the noise voltage generated in the first output winding 232 and the noise voltage generated in the line 25 and the sum of the noise voltage generated in the second output winding 233 and the noise voltage generated in the line 17 The noise voltage transmitted to the first coupling portion 234 and the second coupling portion 235 is canceled by the input smoothing capacitor 11 and the noise generated by the first output winding 232 is applied to the primary side of the power supply device, And the noise component generated in the second output winding 233 and the noise component generated in the line 17 and the line 25 do not appear.

Therefore, EMI generation through the input line 18 and the output line 19 is greatly reduced.

9, the magnitude of the voltage of the noise component to be lowered is adjusted by adjusting the length and the width of the line 16 on the primary side and the line 20 on which the switching current flows, and the first output winding 232 and the second By adjusting the ratio of the number of turns of the output winding 233 to the amount of the generated noise and by adjusting the length and width of the line 17 and the line 25 on the secondary side through which the rectified current flows, The magnitude of the voltage can be matched.

9, when the number of turns of the first output winding 232 and the number of turns of the second output winding 232 is the same, the average potential of the first output winding 232 with reference to the potential of the output smoothing capacitor 15, The average potential of the output winding 232 is opposite in polarity and the magnitude is the same. The capacitive coupling between the first output winding 232 and the first coupling portion 234 and the capacitive coupling between the first output winding 232 and the second coupling portion 234 are the same as the first output winding 232 and the second output winding 232 And the second coupling portion 235 are equal in magnitude and opposite in polarity to each other, so that the noise potential of the switching frequency component is low in the output line 19 and the conductive EMI is also lowered.

Even if the first coupling portion 234 and the second coupling portion 235 are constituted by windings or a shield plate, the effects of lowering the radiation EMI and the conduction EMI are kept equal.

Fig. 10 shows an embodiment of a transformer in which the first coupling portion 234 and the second coupling portion 235 of Fig. 9 are constituted by windings.

10, the input winding 231 is located at the lower end of the bobbin 237 and the first output winding 232 and the second output winding 233 are positioned so as to be magnetically coupled to the input winding 231 The first coupling portion 234 is located on the winding surface between the first output winding 232 and the input winding 231 so as to be capacitively coupled with the first output winding 232 and the second output winding 233, And the second coupling portion 235 is disposed on the winding surface between the second output winding 233 and the input winding 231 so as to be capacitively coupled.

The first output winding 232 and the second output winding 233 are arranged in the same layer with the same number of turns and are structured to generate the same noise voltage in the opposite polarity by the same current flow.

The noise voltage transmitted by the first coupling portion 234 and the first output winding 232 to each other and the noise voltage transmitted by the second coupling portion 235 and the second output winding 233 are opposite to each other The same waveforms are canceled by equalizing the size.

11 is another embodiment of the flyback converter according to the present invention in which one terminal of the first coupling portion 234 and one terminal of the second coupling portion 235 are connected to either one terminal of the input smoothing capacitor 11 FIG.

11 is a power supply device having a structure for lowering EMI by canceling the noise generated in the secondary lines 17 and 25 and the noise generated in the secondary winding so as to be transmitted to the primary side less.

The first coupling portion 234 and the second coupling portion 235 may be formed of a coil or a shield plate.

11, the sum of the noise voltage generated by the first output winding 232 and the noise voltage lowered from the secondary-side line 25 transmitted to the first coupling portion 234 by the first output winding 232, The sum of the noise voltage generated by the second output winding 233 transmitted from the 2 output winding 233 to the second coupling portion 235 and the noise voltage dropped from the secondary winding 17 is supplied to the first coupling portion 234 At the common connection point of one terminal of the second connector 235 and the common terminal of the second connector 235. [ The noise voltage generated by the first output winding 232, the noise voltage generated by the second output winding 233, the noise voltage of the secondary-side line 25, and the noise voltage of the line 17 The generation of EMI through the input line is greatly reduced.

12 is another embodiment of the flyback converter according to the present invention in which output rectifiers 27 and 28 are separately mounted on the first output winding 262 and the second output winding 263, respectively.

12, the noise voltage generated at the first output winding 262 and the noise at the connection point between the line 30 based on one terminal of the output smoothing capacitor 15 and one terminal of the first output winding 262 The voltage is transmitted to the first coupling portion 264 through the first output winding 262 and the noise voltage generated by the second output winding 263 and the output voltage of the output smoothing capacitor 15, The noise voltage at the connection point of one terminal of the first output winding 29 and the second output winding 263 is transmitted to the second coupling section 265 through the second output winding 263.

Since the output rectifier 27 and the output rectifier 28 have almost the same characteristics, the noise voltage generated in the first output winding 262 and the noise voltage generated in the second output winding 263 are almost equal to each other, And the noise voltage of the line 30 are almost similar to each other, so that they are canceled as shown in FIG. However, there is a disadvantage that an offset error due to a difference in characteristics between the output rectifier 27 and the output rectifier 28 may occur.

13 is an embodiment in which the input winding 311 is prevented from being capacitively coupled to the first output winding 312 and the second output winding 313 by the shield plate 314 of the transformer 31, Is a power supply device having a structure for lowering EMI by canceling the noise generated in the line (17 and 25) on the vehicle side and the noise generated in the secondary winding so as to be transmitted to the primary side less.

The sum of the noise voltage generated at the first output winding 312 and the noise voltage at the connection point between the line 25 and one terminal of the first output winding 312 with reference to one terminal of the output smoothing capacitor 15, A line 17 based on the amount of noise delivered to the shield plate 314 through the one output winding 312 and the noise voltage generated by the second output winding 313 and the other terminal of the output smoothing capacitor 15, The noise voltage of the connection point of the one output terminal of the two output windings 313 is transmitted to the shield plate 314 through the second output winding 313 and is equal in magnitude and opposite in polarity with the same waveform, The generation of EMI through the line 18 on the car side is greatly reduced.

The capacitive coupling due to the potential difference between the first output winding 312 and the shield plate 314 and the capacitive coupling due to the potential difference between the second output winding 312 and the shield plate 314 are opposite polarities, And the noise of the switching frequency component is extremely low in the output line 19. This also has the advantage that the conductive EMI is significantly lowered.

Fig. 14 shows an embodiment of the transformer 31 of Fig.

FIG. 15 shows an embodiment in which FIG. 9 is modified. The first coupling portion 324 is used as a part of the input winding 321. FIG.

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 denotes an input smoothing capacitor, 12 denotes a switching element, 13 denotes a transformer, 14 denotes an output rectifier, 15 denotes an output smoothing capacitor, 16 to 20 denotes a line, 22 to 23 denotes a transformer, 24 denotes an output rectifier, 25 denotes a line, Reference numerals 27 and 28 denote output rectifiers, reference numerals 29 and 30 denote a line, reference numerals 31 and 32 denote transformers, reference numeral 101 denotes a capacitor, reference numerals 102 and 103 denote noise sources, reference numerals 104 to 108 denote coupling parts, reference numeral 109 denotes a capacitor, reference numerals 110 and 111 denote noise sources,

Claims (21)

In a switching power supply device,
A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage;
A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage;
A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit; And
And a third coupling unit capacitively coupled to the first coupling unit and the second coupling unit on the other side of the power supply unit and coupled to one terminal of the other side smoothing capacitor,
A noise generated between one terminal of the one smoothing capacitor on one side of the power supply unit and the first coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the first coupling unit, The noise generated by the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the second coupling unit is canceled and EMI is lowered. Type power supply. In a switching power supply device,
A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage;
A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage;
A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit;
A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit;
A third coupling unit capacitively coupled with the first coupling unit at the other side of the power supply unit and coupled to one terminal of the other side smoothing capacitor; And
And a fourth coupling unit capacitively coupled to the second coupling unit on the other side of the power supply unit and coupled to the other terminal of the other side smoothing capacitor,
A noise generated between one terminal of the one smoothing capacitor on one side of the power supply unit and the first coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the first coupling unit, The noise generated by the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the fourth coupling unit on the other side of the power supply unit through the second coupling unit is canceled to lower the EMI. Type power supply. The switching power supply according to claim 2, wherein the first coupling unit and the third coupling unit are constituted by one capacitor, and the second coupling unit and the fourth coupling unit are constituted by one capacitor. Type power supply. In a switching power supply device,
A smoothing capacitor for smoothing an input current of one side of the power supply to supply a voltage;
A second smoothing capacitor for smoothing an input current on the other side of the power supply to supply a voltage;
A first coupling unit coupled to the other end of the power supply unit at one side of the power supply unit;
A second coupling unit coupled to the other end of the power supply unit at one side of the power supply unit;
A third coupling unit coupled to one side of the power supply unit from the other side of the power supply unit; And
And a fourth coupling unit coupled to one side of the power source device from the other side of the power source device,
A noise generated between one terminal of the one smoothing capacitor on one side of the power supply unit and the first coupling unit and transmitted to the third coupling unit on the other side of the power supply unit through the first coupling unit, The noise generated between the other terminal of the one smoothing capacitor and the second coupling unit and transmitted to the fourth coupling unit on the other side of the power source device through the second coupling unit is offset by symmetry and is opposite in polarity, A noise generated between one terminal of the other smoothing capacitor on the other side of the device and the third coupling unit and transmitted to the first coupling unit on one side of the power source device through the third coupling unit and the noise generated on the other side And a fourth coupling unit which is connected between the other terminal of the smoothing capacitor and the fourth coupling unit, And noise transmitted to the second coupler is canceled to lower the EMI. The switching power supply apparatus according to claim 4, wherein the first coupling unit and the third coupling unit are constituted by one capacitor, and the second coupling unit and the fourth coupling unit are constituted by one capacitor. Type power supply. A magnetic energy transfer device for use in a switching power supply device including an input smoothing capacitor having a first terminal and a second terminal, a switching element, a control section, at least one output rectifier, an output smoothing capacitor, and an output line ,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
An output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A first coupling unit for generating a capacitive coupling at a primary side of the magnetic energy transfer device so as to face the output winding; And
And a second coupling portion for generating a capacitive coupling at a primary side of the magnetic energy transfer device, the coupling portion facing the output winding,
Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, Connected to a line connecting between the second terminals of the input smoothing capacitor,
And a second coupling unit connected to the first coupling unit and the output winding, wherein the first coupling unit and the output winding are connected to each other by a capacitive coupling between the one end of the first coupling unit and the first terminal of the input smoothing capacitor, Noise component of the magnetic field is shifted from a line between one terminal of the second coupling portion and the second terminal of the input smoothing capacitor and is capacitively coupled between the second coupling portion and the output winding, Wherein the noise component transmitted to the magnetic sensor is canceled to lower the EMI. A magnetic energy transfer device for use in a switching power supply device including an input smoothing capacitor having a first terminal and a second terminal, a switching element, a control section, at least one output rectifier, an output smoothing capacitor, and an output line ,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And
And a second coupling unit for generating a capacitive coupling on the primary side of the magnetic energy transfer device opposite to the second output winding,
Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, Connected to a line connecting between the second terminals of the input smoothing capacitor,
And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, And the noise component transmitted to the secondary side of the element is canceled to lower the EMI. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And
And a second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy,
One terminal of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and one terminal of the second output winding is connected to the second terminal of the output smoothing capacitor through a connection line Wherein a rectified current having a substantially identical waveform flows through the first output winding and the second output winding,
And a second smoothing capacitor that is lowered by a current flowing in a connection line between one terminal of the first output winding and the first terminal of the smoothing capacitor and is connected to the first output winding through the coupling between the first output winding and the magnetic energy transfer element internal element, A noise component transmitted to a primary side of the transmission element and a current flowing through a connection line between one terminal of the second output winding and the second terminal of the output smoothing capacitor, Wherein a noise component transmitted to a primary side of the magnetic energy transfer device is canceled through coupling with an element inside the device, thereby lowering the EMI. The magnetic energy transfer element according to claim 8, wherein the magnetic energy transfer element internal element is a shield plate capacitively coupled to the first output winding and the second output winding. The magnetic energy transfer element according to claim 8, wherein the magnetic energy transfer element inner element comprises a first shield plate capacitively coupled to the first output coil and a second shield plate capacitively coupled to the second output coil Wherein said magnetic energy transfer element is a magnetic energy transfer element. The magnetic energy transfer element according to claim 8, wherein the magnetic energy transfer element inner element has a first coupling winding, one end of which is connected to one terminal of the input smoothing capacitor and is capacitively coupled with the first output winding, Is a second coupling winding connected to one terminal of the input smoothing capacitor and capacitively coupled to the second output winding. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And
And a second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy,
One terminal of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and one terminal of the second output winding is connected to the second terminal of the output smoothing capacitor through a connection line Wherein a rectified current having a substantially identical waveform flows through the first output winding and the second output winding,
A noise component generated in the first output winding by the noise current flowing in the first output winding and transmitted to the primary side of the magnetic energy transfer element through the coupling between the first output winding and the magnetic energy transfer element inner element, And a noise generated in the second output winding by the noise current flowing in the second output winding and transmitted to the primary side of the magnetic energy transfer element through the coupling between the second output winding and the magnetic energy transfer element internal element And the component is canceled to lower the EMI. The magnetic energy transfer element according to claim 12, wherein the magnetic energy transfer element inner element is a shield plate. The magnetic energy transfer element according to claim 12, wherein the magnetic energy transfer element inner element is a first shield plate and a second shield plate. The magnetic energy transfer element according to claim 12, wherein the magnetic energy transfer element inner element has a first coupling winding whose one terminal is connected to one terminal of the input smoothing capacitor, and one coupling terminal connected to one terminal of the input smoothing capacitor And the second coupling winding is a second coupling winding. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And
And a second coupling unit for generating a capacitive coupling on the primary side of the magnetic energy transfer device opposite to the second output winding,
Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, One end of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and the other end of the first output winding is connected to the one end of the second output winding, Is connected to the second terminal of the output smoothing capacitor through a connection line, a rectified current having a waveform almost coinciding with the first output winding and the second output winding flows,
And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, The noise component transmitted to the secondary side of the device is canceled,
Wherein the first output winding is lowered by a current flowing in a connection line between one terminal of the first output winding and the first terminal of the output smoothing capacitor and is capacitively coupled between the first coupling portion and the first output winding, The noise component transmitted to the primary side of the transmission element and the current flowing in the connection line between the one terminal of the second output winding and the second terminal of the output smoothing capacitor are lowered by the second coupling portion and the second output And the noise component transmitted to the primary side of the magnetic energy transfer element is canceled by the capacitive coupling between the windings, thereby lowering the EMI. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A first coupling unit for generating a capacitive coupling at the primary side of the magnetic energy transfer device opposite to the first output winding; And
And a second coupling unit for generating a capacitive coupling on the primary side of the magnetic energy transfer device opposite to the second output winding,
Wherein one terminal of the first coupling portion is connected to a line connecting one terminal of the input winding and the first terminal of the input smoothing capacitor and one terminal of the second coupling portion is connected to the other terminal of the switching element, One end of the first output winding is connected to the first terminal of the output smoothing capacitor through a connection line and the other end of the first output winding is connected to the one end of the second output winding, Is connected to the second terminal of the output smoothing capacitor through a connection line, a rectified current having a waveform almost coinciding with the first output winding and the second output winding flows,
And a second output terminal connected to the output terminal of the first smoothing capacitor and a second terminal of the input smoothing capacitor, And a capacitive coupling between the one end of the second coupling portion and the second terminal of the input smoothing capacitor and capacitive coupling between the second coupling portion and the second output winding, The noise component transmitted to the secondary side of the device is canceled,
A noise component generated in the first output winding due to a noise current flowing in the first output winding and transmitted to the primary side of the magnetic energy transfer element by capacitive coupling between the first coupling portion and the first output winding, And a noise generated in the second output winding due to a noise current flowing in the second output winding and transferred to the primary side of the magnetic energy transfer element by capacitive coupling between the second coupling portion and the second output winding, And the component is canceled to lower the EMI. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy; And
And a coupling portion which faces the first output winding and the second output winding to generate a capacitive coupling and has one terminal connected to one terminal of the input smoothing capacitor,
The coupling portion blocking the input winding from capacitively coupling to the first output winding and the second output winding,
The capacitive coupling due to the potential difference of the switching frequency component between the coupling portion and the first output winding and the capacitive coupling due to the potential difference of the switching frequency component between the coupling portion and the second output winding are canceled, Wherein said magnetic energy transfer element is a magnetic energy transfer element. An input smoothing capacitor comprising: an input smoothing capacitor having a first terminal and a second terminal; a switching element; a control unit; at least one output rectifier; an output smoothing capacitor having a first terminal and a second terminal; In the magnetic energy transfer device for use in the present invention,
A core of a magnetic energy transfer element;
And a switching element connected between the first terminal of the input smoothing capacitor and one terminal of the switching element, the current flowing through the switching element and the transmission of magnetic energy An input winding that is interrupted;
A first output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A second output winding wound around a core of the magnetic energy transfer element and magnetically coupled to the input winding to draw energy;
A first coupling unit which generates a capacitive coupling with respect to the first output winding and has one terminal connected to one terminal of the input smoothing capacitor; And
And a second coupling unit that generates a capacitive coupling facing the second output winding and has one terminal connected to one terminal of the input smoothing capacitor,
Wherein the first coupling portion blocks the input winding from capacitively coupling with the first output winding and the second coupling portion prevents the input winding from capacitively coupling with the second output winding,
The capacitive coupling due to the potential difference of the switching frequency component between the first coupling portion and the first output winding and the capacitive coupling due to the potential difference of the switching frequency component between the second coupling portion and the second output winding are canceled , And EMI are lowered. A switching power supply device comprising the magnetic energy transfer device according to any one of claims 6 to 19 A manufactured article comprising the switching power supply of any one of claims 1 to 5 and 20.

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