JP2007037379A - Voltage stabilization circuit of switching power supply - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a voltage stabilization circuit of a switching power supply in which waiting power can be reduced by reducing power loss caused by bleeder current flow. <P>SOLUTION: In order to obtain a plurality of DC output voltages from a switching element (S<SB>1</SB>) connected with the primary winding (W<SB>1</SB>) of a transformer T and a plurality of secondary windings (W<SB>2</SB>, W<SB>3</SB>) of the transformer, the stabilization circuit of a switching power supply stabilizes the output voltage by feeding back at least one of the plurality of DC output voltages and controlling on/off of the switching element. Between a first fed back DC output terminal (V<SB>1</SB>) and a second not fed back DC output terminal (V<SB>2</SB>), a current control means (S<SB>2</SB>) is connected and with reference to a first DC output voltage, a fixed ratio of a second DC output voltage is connected with the input terminal of a differential amplifier (IC) and conduction of current control means is controlled by the output from the differential amplifier. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a voltage stabilization circuit at a light load of a switching power supply having a plurality of output voltages.

FIG. 1 shows an example of a conventional voltage stabilizing circuit for a switching power supply having a plurality of output voltages.
1, is switched in accordance with switching signals of the switching element S ₁ which is connected a DC power source e connected in series to the primary winding W ₁ of the transformer T from the control circuit 1.
First induced voltage in the secondary winding W ₃ of transformer T generated by the switching of the switching element S ₁ is rectified by the rectifier elements D _1, as a first DC output voltages V ₁ is smoothed by the smoothing capacitor C ₁ Is output.
The first output voltage V ₁ is detected by the voltage detection circuit ₂ and fed back to the control circuit 1 so that the first output voltage V ₁ is stabilized regardless of the change in the load current I ₁ .

The second induced voltage in the secondary winding W ₂ of transformer T is rectified by the rectifying element D _2, but is output as a DC output voltage V ₂ is smoothed in the second by the smoothing capacitor C _2, to the output voltage There is no feedback.
Then, the spike in the output voltage V ₂ by impact of the second DC output voltage terminal and the magnetic flux leakage is between the ground is connected to the bleeder resistor R _B that current always flows transformer T of the light load (leakage) It is suppressed.

Next, the relationship between the second DC output voltage V ₂ and the bleeder current I _B and the load current I ₂ in the circuit of FIG. 1 will be described with reference to FIG.
FIG. 2A is a diagram showing the relationship of the second DC output voltage V ₂ with respect to the change in the load current I ₂ in the circuit of FIG. 1, and V ₂₀ shows the DC output voltage V ₂ in the steady state. Yes.
As shown in FIG. 2A, the output current I ₂ rapidly increases the _second DC output voltage V ₂ due to the influence of the leakage magnetic flux (leakage) of the transformer T when the load is light (when I ₂ is small).
Its second trend rising DC output voltage V _2, the load current I ₁ increases the larger corresponding to the first DC output voltage hazy feedback, less bleeder current I _B flowing through the bleeder resistor R _B It gets bigger.
The second trend of increase in the DC output voltage V ₂ becomes smaller as the load current I ₁ corresponding to the first output voltage hazy feedback is small, a large bleeder current I _B flowing through the bleeder resistor R _B It gets smaller.

2 (b) is a diagram showing the relationship between the bleeder current I _B to changes in the load current _{I 2} in the circuit of FIG. 1 shows an _{I B = V 2 / R B} .
As shown in FIG. 2 (a), the load current I ₂ is the output voltage V ₂ by impact of the light load leakage flux of the transformer T to (I when ₂ is small) (leakage) increases rapidly, bleeder current I _B also rises rapidly at light loads.

  Reduced power loss in the load current detection circuit, reduced extra power loss in the bleeder resistor, realized sufficient detection sensitivity in detecting standby load current that is sufficiently small compared to the rated load current, false detection The following are known as switching power supply devices that have a stable standby current detection circuit that does not have the same, and a switching power supply device that aims to provide a switching control method.

“At least one direct current is generated by rectifying and smoothing a waveform induced in the secondary winding of the transformer by turning on / off a switching element that forms a closed circuit together with the DC power supply and the primary winding of the transformer. A switching power supply device having a function of lowering the on / off frequency of the switching element when a load current of a predetermined output line becomes smaller than a prescribed value that regulates whether or not to shift to a standby output mode by supplying a voltage A path for supplying a current larger than the specified value is provided separately from a current supplied by rectification and smoothing from a secondary side winding of the transformer for detecting a load current of the predetermined output line, and Switching characterized by comprising load current detecting means coupled to a predetermined output line and having a function of comparing a detected voltage at the coupling point with a reference voltage Source device. "(See Patent Document 1)
JP 2000-350452 A

In the voltage stabilizing circuit of the switching power supply of FIG. 1, the feedback is connected bleeder resistor R _B is constantly have no output circuit depends, than it to prevent surges of voltage under light load, FIGS. 2 (a) As can be seen, the connection of the bleeder resistor alone is not sufficient to prevent a sudden voltage rise, and the regulation is poor.
In addition, since the bleeder resistance is always connected, the bleeder current always flows regardless of the magnitude of the load current. Therefore, there is a problem that power loss always occurs, the efficiency is low, and standby power is increased.

  An example of a problem to be solved by the present invention is to provide a voltage stabilization circuit for a switching power supply capable of reducing standby power by reducing power loss due to bleeder current flowing.

  A stabilization circuit for a switching power supply according to claim 1, wherein a plurality of DC output voltages are obtained from a switching element connected to a primary winding of the transformer and a plurality of secondary windings of the transformer. A switching power supply stabilization circuit that feeds back at least one of the DC output voltages to control the on / off of the switching element to stabilize the output voltage, the first DC output terminal being fed back, and the feedback A current control means is connected between the second DC output terminals which are not fed back or partially fed back, and the constant ratio of the second DC output voltage is set as a differential amplifier based on the first DC output voltage. And the conduction of the current control means is controlled by the output of the differential amplifier.

FIG. 3 shows an example of a voltage stabilizing circuit for a switching power supply having a plurality of output voltages according to an embodiment of the present invention.
In FIG. 3, the switching element S ₁ connected in series with the DC power source e connected to the primary winding W ₁ of the transformer T is switched according to the switching signal from the control circuit 1.
First induced voltage in the secondary winding W ₃ of transformer T generated by the switching of the switching element S ₁ is rectified by the rectifier elements D _1, as a first DC output voltages V ₁ is smoothed by the smoothing capacitor C ₁ Is output.
The first DC output voltage is detected by the voltage detection circuit ₂ and fed back to the control circuit 1 so that the first DC output voltage V ₁ is stabilized regardless of the change in the load current I ₁ .

The second induced voltage in the secondary winding W ₂ of transformer T is rectified by the rectifying element D _2, but is output as a DC output voltage V ₂ is smoothed in the second by the smoothing capacitor C _2, to the output voltage There is no feedback.
Here, the relationship between the first DC output voltage V ₁ and the second DC output voltage V ₂ is (V ₁ <V ₂ ).
Between the second DC output voltage terminal and the first DC output voltage terminal, the second DC output voltage terminal is connected to the first DC output voltage at a light load when the load current I2 of the _second DC output voltage is small. resistor R _B and the control element (transistor) second DC output voltage by impact of the series circuit of the S ₂ is connected to the leakage flux of the transformer T of the light load (leakage) for flowing the bleeder current I _B to the terminal to suppress a surge of V _2.

Then, to the control terminal of the control element S ₂ (base of transistor) is connected the output of the error amplifier IC via a resistor R4, to one input terminal (negative terminal) of the error amplifier, a second DC A series connection point of resistors R ₁ and R ₂ connected between the output voltage terminal and the ground is connected.
Further, the other input terminal of the error amplifier (positive terminal), the first DC output voltage terminal is connected through a resistor R _3.
Further, the series connection point of the resistors R ₁ and R ₂ is connected to the output terminal of the error amplifier via the capacitor C ₃ to ensure stability.
Resistance R _B, together with the bleeder current I _B is prevented from becoming excessive, it performs power sharing between the control element S _2.

Next, the operation of the voltage stabilization circuit of FIG. 3 will be described.
The error amplifier IC amplifies a difference from the constant ratio of the _second DC output voltage V ₂ with reference to the first DC output voltage V ₁ to control the conduction of the control element S ₂ , and sets the resistor R 4. so as to be constant within a second DC output voltage the second DC output voltage V ₂ by passing a bleeder current from the terminal to the first DC output voltage terminal of the load current I ₂ through (light load) To control.
That is, it is possible to suppress the rapid increase in the _second DC output voltage V2 due to the influence of the leakage magnetic flux (leakage) of the transformer T at a light load.

The relationship between the second DC output voltage V ₂ and the bleeder current I _B and the load current I ₂ in the circuit of FIG. 3 will be described with reference to FIG.
FIG. 4A is a diagram showing a relationship of the second DC output voltage V ₂ with respect to a change in the load current I ₂ in the circuit of FIG. 3, and V ₂₀ is a normal voltage (rated voltage).
The second DC output voltage V _TH maintained at light load is
V _TH = V ₁ × (R ₁ + R ₂ ) / R ₂
Determined by.
V _TH −V ₂₀ is set to be equal to or higher than the input offset voltage of the error amplifier IC, and is usually in the range of several mV to 100 mV.
Even if the first DC output voltage V ₁ varies somewhat, V _TH moves at the same rate, so that no malfunction occurs.
Accordingly, as shown in Figure 4a, the output current I ₂ is a light load (when I ₂ is low) spikes DC output voltage V ₂ of the impact or the like of the second magnetic flux leakage (leakage) of the transformer T to the suppression The

FIG. 4B is a diagram showing the relationship of the bleeder current I _B with respect to the change in the load current I ₂ in the circuit of FIG.
As shown by the arrow in FIG. 4B, the bleeder current I _B flows when the load current I ₂ is light (when I ₂ is smaller than I _TH ), and when the load current I ₂ becomes larger than I _TH. Become zero.
Further, the tendency of the bleeder current I _B increases as the load current I ₁ corresponding to the first DC output voltage V ₁ to which feedback is applied increases, and decreases as the load current I ₁ decreases. That, I _TH is dependent proportional to the load current I _1, the load current I ₁ becomes I _TH ≒ 0, i.e. bleeder current I _B is also zero at the vicinity of zero.
I _TH depends on the transformer winding and circuit conditions.

As described above in detail, the stabilization circuit for a switching power supply according to the embodiment of the present invention includes a switching element connected to a primary winding of a transformer and a plurality of direct currents from a plurality of secondary windings of the transformer. In order to obtain an output voltage, a switching power supply stabilization circuit that feeds back at least one of the plurality of DC output voltages and controls on / off of the switching element to stabilize the output voltage, A current control means is connected between the first direct current output terminal and the second direct current output terminal that is not fed back or partially fed back, and the second direct current output voltage is used as a reference, A constant ratio of the DC output voltage is connected to the input terminal of the differential amplifier, and the conduction of the current control means is controlled by the output of the differential amplifier.
As a result, the second output voltage V ₂ can be suppressed from a sudden increase in voltage even if the load current I ₂ is small (I _TH or less) regardless of changes in the load currents I ₁ and I ₂ , and a constant value (V _TH ). Can be maintained.
The function is equivalent to connecting a shunt regulator between the first output voltage terminal and the second output voltage terminal.
Even if the first output voltage V ₁ varies, the second output voltage V ₂ moves at the same ratio, so that no malfunction occurs.
When the load current I ₂ becomes _{equal to} or higher than I _TH , the control element S ₂ is cut off and I _B = 0, so that there is no power loss.
When the load currents I ₁ and I ₂ are close to zero, the second output voltage V ₂ becomes equal to or lower than V _TH (because the leakage spike is reduced), so the control element S ₂ is similarly cut off and the bleeder since the power loss due to the current I _B becomes zero, it can contribute to reduce standby power.

FIG. 1 is a diagram showing a voltage stabilizing circuit of a conventional switching power supply having a plurality of output voltages. FIG. ₂ is a diagram illustrating a relationship among a _second output voltage V ₂ and a bleeder current I _B and a load current I ₂ in the circuit of FIG. 1. FIG. 1 is a diagram showing a voltage stabilization circuit of a switching power supply having a plurality of output voltages according to the present invention. FIG. 4 is a diagram illustrating a relationship among a _second output voltage V ₂ and a bleeder current I _B and a load current I ₂ in the circuit of FIG. 3.

Explanation of symbols

T trans _{W 1} primary winding _W 2, _{W 3} secondary windings e DC power _D 1, _{D 2} rectifying element _C 1, _{C 2} smoothing capacitor _{R 1,} R 2, _{R 3} resistors _{R B} bleeder resistor
S ₁ switching element S ₂ control element (transistor)
IC error amplifier 1 control circuit 2 voltage detection circuit

Claims (4)

In order to obtain a plurality of DC output voltages from a plurality of secondary windings of the transformer and a switching element connected to the primary winding of the transformer, the switching element is fed back by feeding back at least one of the plurality of DC output voltages A switching power supply stabilizing circuit that stabilizes the output voltage by controlling on / off of the power supply,
A current control means is connected between the first DC output terminal being fed back and the second DC output terminal not fed back or partially fed back;
Using the first DC output voltage as a reference, connecting a constant ratio of the second DC output voltage to the input terminal of the differential amplifier,
A switching power supply stabilization circuit, wherein the conduction of the current control means is controlled by the output of the differential amplifier. 2. The stabilization circuit for a switching power supply according to claim 1, wherein the current control means comprises a series circuit of a transistor and a resistor. The current flowing through the current control means becomes zero when the second DC output current exceeds a predetermined value, and becomes zero when the first DC output current and the second DC output current are near zero. The stabilization circuit of the switching power supply according to claim 1 or 2. Constant ratio of the second DC output voltage at a first resistor R ₁ and a second resistor R ₂ divides the second DC output voltage min in the active region of said current control means, a second DC output voltage _{V 2} is,
V ₂ = (R ₁ + R ₂ ) V ₁ / R ₂
The stabilization circuit of the switching power supply according to any one of claims 1 to 3, wherein

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