KR20180127903A - Insulated switching power supply - Google Patents

Abstract

The present invention relates to an insulated switching power source which performs efficient power conversion by a simple configuration. The switching power source comprises: input terminals (1, 2); output terminals (p, n); a transformer (T) including a primary coil (N1) and a secondary coil (N2); a switching element (Q) controlled with on/off thereof; a sub-condenser (C1) connected between one end of the secondary coil and a negative output terminal (n); a choke coil (L) having one end connected to the negative output terminal (n); a first rectifying element (D1) connected between the other end of the second coil and a positive output terminal (p), and conducting current to the positive output terminal (p); a second rectifying element (D2) connected between the other end of the choke coil and the other end of the secondary coil, and conducting current flowing through the secondary coil; a third rectifying element (D3) connected between the other end of the choke coil and one end of the secondary coil, and conducting current flowing through the sub-condenser or the secondary coil; and a smoothing condenser (C2) connected between the output terminals.

Description

[0001] Insulated switching power supply [0002]

The present invention relates to an insulated switching power supply.

Isolated switching power supplies are known that use a transformer to isolate the input side and the output side. When the input is an AC voltage, generally, a DC / DC converter is arranged behind the AC / DC conversion circuit (Patent Documents 1 to 5). When the input is a DC voltage, it is directly input to the DC / DC converter. As a representative method of the DC / DC converter, there are a flyback method and a forward method.

Japanese Patent Application Laid-Open No. 7-31150 Japanese Patent Application Laid-Open No. 8-331860 Japanese Patent Laid-Open No. 2002-10632 Japanese Patent Application Laid-Open No. 2005-218224 Japanese Patent Application Laid-Open No. 2007-37297

In the flyback method of the isolated switching power supply, magnetic energy is accumulated in the transformer during the ON period of the switching element, and the energy is released during the OFF period. In the forward mode, magnetic energy is accumulated in the external choke coil during the ON period of the switching element, and the energy is released during the OFF period. In these methods, the power conversion efficiency of the secondary side can not be said to be sufficient.

Further, in the insulating switching power supply, a high voltage switching device and a snubber circuit capable of withstanding the back electromotive force and the surge voltage generated at the primary side of the transformer at the moment when the switching device is turned off were required. Especially in forward mode, a snubber circuit was needed for self reset. The snubber circuit has a problem that the larger the processing capacity is, the larger the power loss is.

In view of the above problems, the present invention aims at improving the power conversion efficiency of the secondary side in the isolated switching power supply and reducing the internal pressure of the primary side switching device and the processing capacity of the snubber circuit.

In order to achieve the above object, the present invention provides the following configuration. Note that the reference numerals in parentheses are reference numerals in the following drawings and are given for the sake of reference.

According to an aspect of the present invention,

(a) a first input terminal (1) and a second input terminal (2) to which an input voltage is applied,

(b) a positive output terminal (p) and a negative output terminal (n)

(c) a transformer (T) having a primary coil (N1) and a secondary coil (N2) and having one end of the primary coil connected to the first input (1)

(d) a switching element Q which is on / off controlled by a control signal Vg to turn on or off the current path between the other end of the primary coil N1 and the second input terminal 2;

(e) a sub capacitor (C1) connected between one end of the secondary coil (N2) and the negative electrode output terminal (n)

(f) a choke coil L having one end connected to the negative output terminal (n)

(g) a first rectifying element (D1) connected between the other end of the secondary coil (N2) and the positive output terminal (p) for conducting a current flowing from the secondary coil to the positive output terminal (p)

(h) a second rectification element connected between the other end of the choke coil (L) and the other end of the secondary coil (N2) for conducting a current flowing from the choke coil (L) to the secondary coil (D2)

(i) is connected between the other end of the choke coil L and one end of the secondary coil N2, and the current flowing from the choke coil L to the sub-condenser C1 or the secondary coil N2 A third rectifying element D3 for conducting the second rectifying element D3,

(j) a smoothing capacitor (C2) connected between the positive output terminal (p) and the negative electrode output terminal (n).

According to the present invention, it is possible to improve power conversion efficiency in an insulated switching power supply.

Fig. 1 is a view schematically showing an example of a circuit configuration of an embodiment of the insulated switching power supply of the present invention.
2 is a view schematically showing the flow of current in the ON period of the circuit configuration shown in Fig.
Fig. 3 is a diagram schematically showing the potential relationship in the on period in the secondary side of the circuit configuration shown in Fig. 1. Fig.
4 is a diagram schematically showing the current flow in the off period of the circuit configuration shown in Fig.
5 is a diagram schematically showing the potential relationship in the off period in the secondary side of the circuit configuration shown in Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of an insulated switching power supply according to the present invention will be described with reference to the drawings showing embodiments.

 (1) Circuit configuration

Fig. 1 is a diagram schematically showing an example of a circuit configuration of an embodiment of an insulated switching power supply (hereinafter referred to as "switching power supply") of the present invention. In the following, the present invention will be described by taking the case of a DC / DC converter into which a DC voltage is input as an embodiment. However, the switching power supply of the present invention is a power conversion device that can function in the same manner even when a voltage of a certain waveform such as a square wave or an alternating current, in which a voltage fluctuates, in addition to a constant DC voltage and outputs a DC voltage.

The switching power supply of the present invention is of an insulation type that electrically insulates the input side and the output side. For this purpose, a transformer (T) is installed. The transformer T basically has one primary coil N1 and one secondary coil N2.

The winding start end of each coil is indicated by a black circle. The term "one end" and "the other end" in this specification mean a combination of "take-up start" and "take-off end" in the case of a coil and a combination of "take-up end" And the like. In the transformer T, the polarities of the primary coil N1 and the secondary coil N2 are the same as those of the conventional flyback method.

The input voltage is applied between the first input terminal 1 and the second input terminal 2. One end (winding start end in this example) of the primary coil N1 of the transformer T is connected to the first input terminal 1. Here, the second input terminal 2 is the input-side reference potential terminal.

The secondary side of the transformer T is provided with a positive output terminal p and a negative electrode output terminal n to which a DC voltage is output. Here, the negative electrode output stage (n) is the secondary side reference potential stage. An output voltage is applied to a load (not shown) connected between the positive output terminal p and the negative output terminal n, and an output current flows.

One end of the switching element Q is connected to the other end (winding end in this example) of the primary coil N1 of the transformer T. The other end of the switching element Q is connected to the second input terminal 2. The switching element Q has a control terminal, and the control terminal is on / off-controlled to turn on or off the current path between the other terminal of the primary coil N1 and the second input terminal 2. [

The control terminal of the switching element Q is controlled by the control signal Vg. The control signal Vg is, for example, a PWM signal having a pulse waveform of a predetermined frequency and duty ratio. In the illustrated example, the switching element Q is an n-channel type MOSFET (hereinafter referred to as "FET Q"), one end is the drain, the other end is the source and the control end is the gate. In this case, the control signal Vg is a voltage signal.

Further, for example, an IGBT or a bipolar transistor may be used as a switching element other than the FET.

One capacitor (hereinafter referred to as "sub capacitor") C1 is connected between one end of the secondary coil N2 of the transformer T (the winding start end in this example) and the negative electrode output terminal n. A smoothing capacitor C2 is connected between the positive output terminal p and the negative output terminal n.

A first rectifying element D1 is connected between the other end of the secondary coil N2 of the transformer T and the positive output terminal p. The first rectifying element D1 is connected in such a direction that the current flowing from the secondary coil N2 to the positive output terminal p becomes conductive when the forward bias is applied and the current is blocked when the reverse bias is applied. When the first rectifying element D1 is, for example, a diode, the anode of the diode D1 is connected to the other end of the secondary coil N2, and the cathode is connected to the positive output terminal p.

The circuit on the secondary side of the transformer (T) has a choke coil (L). One end of the choke coil L is connected to the negative electrode output terminal n.

The second rectifying element D2 is connected between the other end of the choke coil L and the other end of the secondary coil N2 of the transformer T. [ The second rectifying element D2 conducts a current flowing from the other end of the choke coil L to the other end of the secondary coil N2 when the forward bias is applied and is connected in a direction to block the current when the reverse bias is applied . When the second rectifying element D2 is, for example, a diode, the anode of the diode D2 is connected to the other end of the choke coil L, and the cathode is connected to the other end of the secondary coil N2.

The third rectifying element D3 is connected between the other end of the choke coil L and one end of the secondary coil N2 of the transformer T. [ The third rectifying element D3 conducts a current flowing from the other end of the choke coil L to one end of the secondary coil N2 or the sub capacitor C1 when the forward bias is applied, As shown in Fig. When the third rectifying element D3 is, for example, a diode, the anode of the diode D3 is connected to the other end of the choke coil L, and the cathode is connected to one end of the secondary coil N2.

It is preferable that the diodes D1, D2 and D3 have a small forward voltage drop and perform a high-speed operation. As another example of the rectifying element other than the diode, another element or circuit having an equal rectifying function can be used.

Although not shown, it is preferable to have a control section for generating the control signal Vg. As an example, the control unit detects the input voltage and the output voltage, determines the duty ratio of the control signal Vg based on the detected input voltage and the output voltage, and generates the control signal Vg based thereon. As a main part of the control unit, a PWMIC can be used.

 (2) Description of operation

The operation of the circuit configuration shown in Fig. 1 will be described with reference to Figs. 2 to 5. Fig. Except for the transient operation at the start and at the time of stopping the circuit, the operation in the case where the circuit is in the normal state will be described.

 (2-1) Details of the operation of the primary side and the secondary side in the ON period

Fig. 2 schematically shows a current flow (dotted line arrow) in the ON period in the circuit configuration shown in Fig.

 [On period: Primary side]

On the primary side of the transformer, when the control signal Vg is turned on in the on period, the FET Q is turned on and the current path is conducted. In the primary coil N1 of the transformer T, the input current i1 due to the input voltage flows in the following path.

Input current i1: first input terminal 1? Transformer primary coil N1? FETQ? Second input terminal 2?

 [On period: secondary side]

In Fig. 2, for convenience of explanation, the other end of the secondary coil N2 of the transformer T is referred to as point a, and the other end of the secondary coil N2 is referred to as point b. Further, the other end of the choke coil L is set as d point, the positive output terminal p is set as the point c, and the negative output terminal n is set as the e point.

Fig. 3 is a diagram schematically showing a potential relationship between points a to e of the transformer secondary side in the ON period. The operation of the transformer secondary side in the ON period will be described with reference to FIG. In the steady state, the sub-condenser C1 and the smoothing capacitor C2 are charged with substantially constant voltage Vc1 and voltage Vc2, respectively, except for fluctuations in ripple.

The input current i1 flows in the primary coil N1 and an electromotive force Vn2 is generated in the secondary coil N2 (the term "electromotive force" and "counter electromotive force" in this specification are used in the meaning of voltage) . As shown in the potential relationship diagram of Fig. 3, the electromotive force Vn2 has a high potential at point b and a low potential direction at point a. The diode D1 has a reverse bias due to the relationship between the a-point potential and the c-point potential, so that no current flows. For the load, the discharge current from the smoothing capacitor C2 is supplied.

When the potential of the point b exceeds the potential of one end of the sub capacitor C1 due to the electromotive force Vn2, the current i2 flows to the following path.

Current i2: transformer secondary coil b point → sub-capacitor C1 → choke coil L → diode D2 → transformer secondary coil a point

The electromotive force V _L is generated in the choke coil L2 by the current i2 flowing through the choke coil _L and the d point potential becomes lower than the e point of the negative electrode output terminal n. Since the diode D2 conducts, the transformer secondary coil a point has the same potential as the d point voltage. The diode D3 is reverse-biased by the relationship between the point-B potential and the point-D potential, so that no current flows.

The current i2 flowing to the secondary side during the ON period flows in the direction of charging the sub condenser C1. As a result, electric energy is accumulated in the sub-condenser C1. In addition, magnetic energy is accumulated in the choke coil L by exciting the choke coil L by the current i2.

In the normal forward method, magnetic energy is accumulated in the external choke coil in the ON period, and magnetic energy is accumulated in the transformer in the ON period in the ordinary flyback method. On the other hand, in this circuit, electric energy is accumulated in the sub capacitor C1 during the ON period, and magnetic energy is accumulated in the choke coil L. Thus, in this circuit, the power conversion efficiency can be improved.

In this circuit, since the degree of accumulation of magnetic energy in the transformer T in the ON period is small, the processing capacity of the snubber circuit for magnetic reset can be reduced.

 (2-2) Details of the operation of the primary side and the secondary side in the off period

4 is a diagram schematically showing a current flow (dotted line arrow) in the off period in the circuit configuration of Fig.

 [Off period: primary side]

On the transformer primary side, when the control signal Vg is turned off, the FET Q is also turned off and the switch is opened. The current of the primary coil N1 of the transformer T is cut off and the current becomes zero. Whereby a counter electromotive force is generated in the primary coil N1 and the secondary coil N2 of the transformer T, respectively.

 [Off period: secondary side]

Fig. 5 is a diagram schematically showing a potential relationship between points a to e of the secondary side of the transformer in the off period. The operation of the secondary side in the off period will be described with reference to Fig.

The back electromotive force Vn2 generated in the secondary coil N2 of the transformer T is a low potential on the point b and a high potential direction on the point a as shown in the potential relationship diagram of Fig. When the a point potential exceeds the c point potential which is the potential of one end (positive electrode output terminal (p)) of the smoothing capacitor C2, the diode D1 becomes forward biased and the current i21 flows into the following path.

Current (i21): Transformer secondary coil a point → Diode (D1) → Load (or smoothing capacitor C2) → Sub-capacitor (C1) → Transformer secondary coil b point

Further, the choke coil L generates the counter electromotive force (V _L ) so as to maintain the current in the ON period. In this counter electromotive force (V _L ), the point d is the high potential and the point e is the low potential direction. When the counter electromotive force V _L exceeds the potential of one end of the sub condenser C1, the diode D3 conducts, and the currents i22 and i23 flow in the following paths.

Current i22: choke coil L → diode D3 → sub-capacitor C1

Current i23: choke coil L → diode D3 → transformer secondary coil → diode D1 → load (or smoothing capacitor C2)

The diode D2 is reverse-biased by the relationship between the a-point potential and the d-point potential, so that no current flows.

The current i21 in the off period is a discharge current that discharges the electric energy stored in the sub capacitor C1 in the on period and is supplied to the load or charges the smoothing capacitor C2. On the other hand, the current i22 and the current i23 in the off period emit magnetic energy stored in the choke coil L in the on period. The current i22 flows in the direction of charging the sub condenser C1 to supplement the electric energy lost by the discharge of the sub condenser C1. Further, the current i23 is supplied to the load together with the current i21 or charges the smoothing capacitor C2. Thus, the magnetic energy stored in the choke coil L in the on period is converted into electric energy in the off period.

The counter electromotive force Vn2 generated in the secondary coil N2 of the transformer T during the off period is suppressed by the voltage VC1 charged in the sub capacitor C1 during the on period. That is, the counter electromotive force Vn2 becomes smaller by the voltage VC1 than the counter electromotive force generated in the secondary coil N2 in the absence of the sub-condenser C1. As a result, since the counter electromotive force (including the surge voltage) generated in the primary coil N1 of the transformer T at the moment when the FET Q is turned off is also reduced, the breakdown voltage required for the FET Q on the primary side can be reduced. Also, the processing capacity of the snubber circuit for suppressing the surge voltage can be reduced.

 (2-3) Arrangement of action and effect

The switching power supply of the present invention functions to accumulate electric energy in the sub-condenser and accumulate magnetic energy in the choke coil in the transformer secondary side during the ON period. In the off period, electric energy is discharged from the sub-condenser and supplied to the load, and at the same time, the electric energy of the sub-condenser is supplemented by the magnetic energy of the choke coil. As a result, the power conversion efficiency of the secondary side is improved.

Since the choke coil on the secondary side contributes to the charging of the sub capacitor even in the ON period and the OFF period, the use efficiency of the choke coil is improved as compared with the forward type external choke coil.

The internal voltage of the switching element can be reduced in that the counter electromotive force and the surge voltage generated in the primary coil at the moment when the switching element is turned off are suppressed by the voltage across both ends of the sub capacitor. In addition, since the processing capacity of the snubber circuit for overvoltage suppression can be reduced, the power loss is reduced.

1: first input stage
2: second input terminal (input side reference terminal)
P: positive output stage
N: Negative electrode output terminal (output side reference potential)
T: Transformer
N1: primary coil
N2: Secondary coil
Q: Switching element (FET)
D1, D2, D3: rectifying element (diode)
C1: Subcondenser
C2: Smoothing capacitor
L: choke coil

Claims (1)

(a) a first input terminal (1) and a second input terminal (2) to which an input voltage is applied,
(b) a positive output terminal (p) and a negative output terminal (n)
(c) a transformer (T) having a primary coil (N1) and a secondary coil (N2) and having one end of the primary coil connected to the first input (1)
(d) a switching element Q which is on / off controlled by a control signal Vg to turn on or off the current path between the other end of the primary coil N1 and the second input terminal 2;
(e) a sub capacitor (C1) connected between one end of the secondary coil (N2) and the negative electrode output terminal (n)
(f) a choke coil L having one end connected to the negative output terminal (n)
(g) a first rectifying element (D1) connected between the other end of the secondary coil (N2) and the positive output terminal (p) for conducting a current flowing from the secondary coil to the positive output terminal (p)
(h) a second rectification element connected between the other end of the choke coil (L) and the other end of the secondary coil (N2) for conducting a current flowing from the choke coil (L) to the secondary coil (D2)
(i) is connected between the other end of the choke coil L and one end of the secondary coil N2, and the current flowing from the choke coil L to the sub-condenser C1 or the secondary coil N2 A third rectifying element D3 for conducting the second rectifying element D3,
(j) a smoothing capacitor (C2) connected between the positive output terminal (p) and the negative electrode output terminal (n).

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