JPH10210748A - Dc stabilizing power unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To quicken the output response of an AF circuit, and also, remove the start up trouble of a converter caused by the drop of the output voltage of the AF circuit by the sudden increase of load, in a DC stabilizing power unit where an active filter(AF) consisting of a step-up chopper circuit and an insulation type of step-down converter are combined for power factor improvement. SOLUTION: This device comprises an AF circuit 1, an insulation type of step-down converter 2, an AF control circuit 3, a converter control circuit 4, a feedback signal generating circuit 5, and a voltage detecting circuit 6. In this case, the feedback signal generating circuit 5 is provided with an auxiliary winding 21, and this output voltage Voffset generated in this auxiliary winding 213 is added as an offset value to the output voltage detection value VR2 of an active filter, and it is made the feedback voltage Vmon of AF control.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device, and more particularly, to a DC stabilized power supply device in which an active filter including a boost chopper circuit is provided in a front stage for improving a power factor and an insulated type step-down converter is combined in a rear stage.

[0002]

2. Description of the Related Art In a stabilized DC power supply, an active filter circuit (hereinafter, referred to as an AF circuit), which is a boost chopper circuit, is generally provided before an isolated buck converter as a means for improving a power factor or expanding an input voltage range. That)
For example, using a power conversion circuit shown in FIG. 3 of JP-A-3-173354,
It is common as a switching power supply device shown in FIG.

A power conversion circuit disclosed in Japanese Patent Application Laid-Open No. 3-173354 relates to a configuration of an AF circuit.
If the output response of the AF circuit is made faster, the third harmonic of the input current increases, so that the response to the voltage fluctuation of the output of the AF circuit cannot be made faster. was there. Further, Japanese Patent Laid-Open No. 4-1
The switching power supply device disclosed in Japanese Patent No. 12676 also has the same problem as the power supply conversion circuit.

When the post-stage converter of the AF circuit rises (during start-up), the voltage of the output of the AF circuit decreases due to the response delay of the AF circuit due to a sudden increase in the load.
There is a possibility that the voltage of the output of the F-circuit may become lower than the stop voltage of the subsequent converter, and in this case, there is a problem that the starting failure of the latter converter occurs.

[0005]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problem, the present invention provides an insulated step-down converter having an active filter composed of a step-up chopper circuit for improving a power factor at a front stage and a converter transformer at a rear stage. In a DC stabilized power supply device combined with a converter, the output response of the AF circuit is accelerated, and the voltage of the output of the AF circuit is prevented from lowering due to a sudden increase in the load when the latter-stage converter starts up (during start-up). It is an object of the present invention to prevent a voltage from becoming lower than a stop voltage of a post-stage converter so that a start-up failure of the converter does not occur.

[0006]

To this end, the present invention provides
In a DC stabilized power supply device in which an active filter composed of a step-up chopper circuit is placed in the front stage for power factor improvement and an insulated step-down converter is combined in the subsequent stage, an auxiliary winding is provided in the converter transformer and generated in the auxiliary winding. A feedback signal generation circuit is provided which adds the output voltage (Voffset) as an offset value to the active filter output voltage detection value (V _R2 ) to provide a feedback voltage for active filter control.

According to the present invention, in the DC stabilized power supply, switching means controlled to change the output voltage of the active filter by the output current of the converter or an external signal is connected to the output terminal of the auxiliary winding of the converter transformer. .

According to the present invention, a boost chopper circuit is provided at a front stage, and an insulation type converter is combined at a rear stage to improve a power factor of a stabilized DC power supply. An auxiliary winding is provided in a transformer of the converter. A second output voltage is generated, the output voltage is added as an offset value to the detected voltage value of the AF circuit output voltage, and the added voltage is fed back to the control circuit of the AF circuit.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a DC stabilized power supply according to the present invention will be described below with reference to FIG.
The stabilized DC power supply according to the present invention includes: an AF circuit 1;
A post-stage converter comprising an isolated type step-down converter 2;
It comprises an F control circuit 3, a converter control circuit 4, and a feedback signal generation circuit 5.

The AF circuit 1 includes a full-wave rectifier 11, a choke coil 12 inserted in series with one output of the rectifier 11, an output of the choke coil 12 and the rectifier 11.
A switching element 13 connected between the other outputs of the
Rectifier 14 connected to the output of choke coil 12
And a capacitor 15 connected between the output of the rectifier 14 and the other output of the rectifier.

The insulated step-down converter 2 is configured as a feed-forward converter. A primary winding 211 is connected to an output of the AF circuit 2 via a switching element 22, and a transformer 21 and a secondary winding of the transformer 21 are connected. Line 2
A rectifier 23 connected in series with the rectifier 23; a rectifier 24 connected between the output of the rectifier 23 and another output of the secondary winding 212 of the transformer 21;
A choke coil 25 connected in series to the connection point 4;
It is constituted by a capacitor 26 connected between the output of the choke coil 25 and another output of the secondary winding 212.

The AF control circuit 3 includes a switching element 13
, A desired boosted DC voltage Vout can be obtained. Also, since the input current is controlled so as to be similar to the waveform of the input voltage, the input current becomes a sine wave, and the power factor can be improved.

The isolated type step-down converter 2 steps down the step-up DC voltage output Vout, feeds back an error voltage Verror of the converter output voltage Vcout detected by the voltage detection circuit 6 to the converter control circuit 4, and
, A desired low constant voltage can be obtained as converter output voltage Vcout.

The feedback signal generation circuit 5 includes an auxiliary winding 213 provided on the transformer 21 of the insulation type step-down converter 2;
Rectifier 51 connected in series to the output of auxiliary winding 213
A capacitor 52 connected between the output of the rectifier 51 and another output of the auxiliary winding 213;
Rectifier 53 connected to the connection point of
And an offset voltage detecting resistor 54 connected between the output of the rectifier 53 and another output of the auxiliary winding 213.
The offset voltage detecting resistor 54 and the rectifier 53
, And a voltage detection resistor 53 and a voltage detection resistor 54 connected between the output of the AF circuit 1 and the other end of the offset voltage detection resistor 54. Output terminal.

[0015]

When the output voltage of the AF circuit 1 is Vout, the output voltage of the auxiliary winding is Voffset, and the constants are K ₁ and K ₂ in the DC stabilized power supply device configured as described above, feedback is provided to the AF control circuit 3. The monitoring voltage Vmon is represented by the following equation (1). _{Vmon = K 1 · Vout + K} 2 · Voffset ...... (1)

Here, assuming that the auxiliary winding voltage Voffset before starting the post-stage converter 2 is 0 (V) and the auxiliary winding voltage Voffset after starting is A ₁ (V), the monitoring voltage Vm after starting is assumed.
Since on becomes higher by being added by K ₂ · A ₁ (V), the AF control circuit 3 controls the AF circuit 1 to reduce this voltage. That is, if K ₁ , Vout, K ₂ , and Voffset are set so that the voltage of the AF circuit 1 becomes a desired voltage after the start, the output voltage Vout of the AF circuit 1 before the start of the post-stage converter 2 becomes the desired value. It is assumed that the voltage is lower than the voltage by K ₂ · A ₁ (V) and is controlled, and the output voltage Vout of the AF circuit 1 becomes equal to or lower than the stop voltage of the post-stage converter 2 when the post-stage converter 2 starts up and suddenly increases in load. Can be improved.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a stabilized DC power supply according to the present invention will be described below with reference to FIG. 2, the same components as those in FIG. 1 are denoted by the same reference numerals. The DC stabilized power supply according to this embodiment includes an AF circuit 1, a post-stage converter including an insulated step-down converter (feed-forward converter) 2, an AF control circuit 3, a converter control circuit 4, and a feedback signal generation circuit 5. It is composed of

The AF circuit 1 is the same as the AF circuit 1 shown in FIG. The isolated step-down converter 2 is configured such that the current transformer 27 is connected between the other output terminal of the secondary winding 212 of the isolated step-down converter 2 shown in FIG.
The only difference is that the next winding 271 is connected.
Others are the same. The AF control circuit 3 includes an error amplifier 31
And a reference voltage Vref ₃ 32. Voltage detection circuit 6
Is composed of voltage detection resistors 61 and 62, an error amplifier 63, and a reference voltage Vref ₆ 64.

The feedback signal generating circuit 5 is connected to the secondary winding 272 of the current transformer 27 connected in series to the resistor 58 connected to the other end of the auxiliary winding 213, and to the other end of the resistor 58. A rectifier 59 and a resistor 50 are connected to one end of the rectifier 53, and the switching means 5 is connected between the other end of the rectifier 53 and one end of the voltage detection resistor 54.
7 is different from the feedback signal generation circuit 5 shown in FIG. The switching of the switching means 57 is controlled by the voltage of the resistor 50.

With such a circuit configuration,
Converter startup previous AF circuit 1 of the output voltage Vout (the voltage across the capacitor 15), the detection resistor _{(R 1, R 2, R} 3)
Via 56, 55, 54, the error amplifier 31 in the AF control circuit compares and controls the reference voltage Vref ₃ . The induced voltage of the auxiliary winding 213 which is provided to the transformer 21 of the converter 2, both ends of the rectifier 51 and a rectifier with a capacitor 52 and smoothing creating an offset voltage Voffset, AF circuit through the rectifier 53 output voltage detecting resistor R ₃ 54 Is added to Here, the detection resistor R before the converter is started
_{If the} voltage at both ends of 354 is VR ₃ (V), the Voffset voltage is set to A ₁ (V) in advance so that A ₁ > VR ₃ .

[0021] With this configuration, after starting the insulated drop converter 2, the voltage across the sensing resistor R ₃ is the voltage across VR ₃ (V) higher than the voltage A ₁ of the converter startup before detection resistor R ₃ (V ), And the voltage input to the error amplifier 31 is (A ₁ −VR ₃ ) as compared with that before the start of the converter 2.
(V). However, the AF control circuit 3 sets the input voltage (VR ₂ + A ₁ ) of the error amplifier 31 to the reference voltage Vref ₃
And controls the same so as to output voltage when, as the voltage across VR ₂ of the detection resistor R ₂ 55 is _{(A 1 -VR 3) (V} ) low, to lower the output voltage Vout of the AF circuit 1. That is, the output voltage V of the AF circuit 1 before the start of the converter 2
out is higher than the output voltage Vout of the AF circuit 1 after startup. In this way, if the output voltage Vout of the AF circuit 1 before the start of the converter 2 is adjusted to be higher in advance in view of the AF circuit output voltage drop (A ₁ -VR ₃ ), the start of the post-stage converter 2 The voltage drop at the time can be cancelled, and the voltage drop to the stop voltage of the converter 2 does not occur, so that the starting failure of the downstream converter can be improved.

Further, the output of the rectifier 53 and the detection resistor R ₃
A switching element 57 is provided between the current transformer 2 and the circuit current of the isolated step-down converter 2.
7, the switching element 57 is controlled by the output thereof, and when the circuit current of the converter 2 becomes higher than a certain value, the switching element 57 is switched from ON to OFF. When the circuit current of converter 2, that is, the load current, exceeds a certain value, switching element 57 is turned off.
And the output voltage of the AF circuit 2 acts so as to increase in the same manner as in the state before the start-up.
A decrease in the output voltage Vout of the F circuit 1 can be reduced.

In the present embodiment, the feedback voltage Vmon is changed by the load current of the converter 2. However, the control of the switching element 57 is not limited to this. It may be taken out of the circuit, in which case a signal may be given to turn off the switching element 57 only when the motor is started. As a result, before the load increases, A
The output voltage of the F circuit 1 can be set high,
It is possible to prevent the converter 2 from stopping due to a sudden increase in the load.

Further, as shown in FIG. 3, if the switching element 57 of the feedback signal generation circuit 5 is constituted by a transistor or the like and the base voltage is changed, the output voltage of the AF circuit 1 is changed in multiple stages. And finer control becomes possible.

Further, the same function can be obtained even if the voltage VR ₃ across the detection resistor R ₃ 54 can be changed continuously instead of the switching element 57.

In the present embodiment, the combination of the AF circuit 1 and the feed-forward converter 2 has been described. However, the converter 2 at the subsequent stage is not limited to the feed-forward converter, but may be an insulating type such as a ring choke converter or a flyback converter. Naturally, even a step-down converter can be configured.

[0027]

As described above, according to the stabilized DC power supply of the present invention, the output response of the AF circuit is made faster, and the AF circuit is provided by a sudden increase in the load when the post-stage converter starts up (start-up). The output voltage of the AF circuit can be prevented from lowering, and the output voltage of the AF circuit does not become lower than the stop voltage of the post-stage converter.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing a configuration concept of a stabilized DC power supply device according to the present invention.

FIG. 2 is a specific circuit diagram showing one embodiment of a stabilized DC power supply device according to the present invention.

FIG. 3 is a specific circuit diagram showing another embodiment of the stabilized DC power supply device according to the present invention.

[Brief description of reference numerals]

1 AF circuit, 11 full-wave rectifier, 12 choke coil, 13 switching element, 14 rectifier,
15 capacitors, 2 isolated buck converters,
21 transformer, 211 primary winding, 212 secondary winding, 213 auxiliary winding, 22 switching element,
23, 24 rectifier, 25 choke coil, 2
6 Capacitor, 27 Current transformer, 271
Primary winding, 272 secondary winding, 3 AF control circuit,
31 error amplifier, 32 reference voltage, 4 converter control circuit, 5 feedback signal generation circuit, 50, 58 resistor, 51, 53, 59 rectifier, 52 capacitor, 54, 55, 56 voltage detecting resistor, 57 switching means, 6 voltage Detection circuit, 61, 62 voltage detection resistor, 63 error amplifier, 64 reference voltage.

Claims (2)

[Claims] 1. An active filter for controlling an output of an active filter in a DC stabilized power supply device in which an active filter including a boost chopper circuit is provided in a front stage for improving a power factor and an insulated buck converter having a converter transformer is provided in a subsequent stage. A filter control circuit, an auxiliary winding provided in a converter transformer of an isolated step-down converter, and an output voltage (Voffset) generated in the auxiliary winding are added as an offset value to an active filter output voltage detection value ( _VR2 ). And a feedback signal generating circuit for providing a feedback voltage for active filter control. 2. The DC stabilization device according to claim 1, wherein switching means controlled to change the output voltage of the active filter by an output current of the converter or an external signal is connected to an output terminal of the auxiliary winding of the converter transformer. Power supply.