JPH05328717A - Power control circuit - Google Patents

Abstract

PURPOSE:To provide a power control circuit, which can be downsized and formed into IC, in a switching power supply. CONSTITUTION:This apparatus is provided with an error amplifier 2 for amplifying the difference between input voltage and reference voltage source 3, with a first voltage detection circuit 5 for outputting a signal, when the output voltage of the error amplifier 2 exceeds a preset threshold value for a certain period of time or longer, and with a second voltage detection circuit 7 for outputting a signal, when the output voltage of the error amplifier 2 is lower than a preset threshold value for a certain period of time or longer. Further, the apparatus is equipped with an OR circuit 9 for obtaining the logical sum of the outputs of the first voltage detection circuit 5 and second voltage detection circuit 7, with a latch circuit 10 for outputting a latch signal on the basis of the output of the OR circuit 9, and with a pulse-width conversion circuit 1 for generating a signal with pulse width corresponding to the output voltage of the error amplifier 2 simultaneously with the output from a triangular-wave generation circuit 4 and for outputting or stopping the pulse signal on the basis of the output signal of the latch circuit 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply control circuit,
In particular, it relates to a power supply control circuit in a switching power supply.

[0002]

2. Description of the Related Art As shown in FIG. 3, a conventional power supply control circuit includes a circuit 20 for directly detecting an output voltage at a DC voltage level, an overvoltage detection circuit 11 for detecting an overvoltage of the output voltage, and an output. An undervoltage detection circuit 12 that detects a voltage shortage of voltage, and an OR circuit 9 that obtains a logical sum of the output signal of the overvoltage detection circuit 11 and the output signal of the undervoltage detection circuit 12
And an output voltage control circuit 23 that controls the output voltage based on the output signal of the OR circuit 9.

Here, the output voltage control circuit 23 includes a triangular wave generator 4 for generating a triangular wave, a reference voltage source 3, and an error amplifier 2 for amplifying an error between the reference voltage of the reference voltage source 3 and the output voltage. A latch circuit 10 that outputs a latch signal based on the output signal of the OR circuit 9, and a pulse width that generates a pulse signal having a pulse width corresponding to the output voltage of the error amplifier 2 in synchronization with the triangular wave signal from the triangular wave generator 4. The conversion circuit 1 is provided.

In order to simplify the circuit, the switching power supply includes the pulse width conversion circuit 1, the latch circuit 10, the triangular wave generator 4, and the OR circuit 9 on the primary side, the error amplifier 2, the reference voltage source 3, and the overvoltage detection circuit 11. A so-called primary control circuit in which the undervoltage detection circuit 12 is installed on the secondary side is generally used. At this time, a photocoupler is used for signal transmission between the primary and secondary sides.

[0005]

However, in the above-mentioned conventional example, three photocouplers for the output of the error amplifier, the output of the overvoltage detection circuit and the output of the undervoltage detection circuit are required, and the overvoltage detection circuit and the undervoltage detection circuit are required. Since a detection circuit independent of the detection circuit is required, there is a disadvantage that the number of parts is large and it cannot be downsized or integrated into an IC.

[0006]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power supply control circuit which is capable of improving the disadvantages of the conventional example and, more particularly, of reducing the size and the IC of a switching power supply.

[0007]

Therefore, in the present invention, a reference voltage source, an error amplifier for amplifying the difference between the input voltage and the reference voltage source, a triangular wave generating circuit for generating a triangular wave, and an error for a certain time or more. A first voltage detection circuit that outputs a signal when the output voltage of the amplifier exceeds a preset threshold value, and the output voltage of the error amplifier falls below the preset threshold value for a certain period of time or longer. And a second voltage detection circuit for outputting a signal, an output of the first voltage detection circuit, and a second
An OR circuit that obtains a logical sum with the output of the voltage detection circuit of
A latch circuit that outputs a latch signal based on the output of this OR circuit, and a pulse signal that has a pulse width corresponding to the output voltage of the error amplifier in synchronization with the triangular wave signal from the triangular wave generation circuit, and the output signal of the latch circuit. And a pulse width conversion circuit that outputs or stops the pulse signal based on the above. This is intended to achieve the above-mentioned object.

[0008]

The error amplifier amplifies and outputs the difference between the input voltage and the reference voltage source.

The pulse width conversion circuit generates a pulse signal having a pulse width corresponding to the output voltage of the error amplifier in synchronization with the triangular wave signal from the triangular wave generation circuit.

The second voltage detection circuit measures the time when the output voltage of the error amplifier falls below the threshold value of the second voltage detection circuit, and if the voltage shortage continues for a preset time or longer, the output signal is output. Change.

The first voltage detection circuit measures the time when the output voltage of the error amplifier exceeds the threshold value of the first voltage detection circuit, and outputs the output signal when the overvoltage continues for a preset time or longer. Change.

The latch circuit stops the output of the pulse signal from the pulse width conversion circuit when the output signal of the first voltage detection circuit or the output signal of the second voltage detection circuit changes.

[0013]

DETAILED DESCRIPTION OF THE INVENTION An embodiment of the present invention will be described below with reference to FIGS. In the embodiment of FIG. 1, a reference voltage source 3, an error amplifier 2 that amplifies a difference between an input voltage and the reference voltage source 3, a triangular wave generation circuit 4 that generates a triangular wave, and a preset time elapses. A first mask timer 6 that outputs a signal, and a first mask timer 6 that changes the output signal when the output voltage of the error amplifier 2 exceeds a preset threshold value for a time longer than the time set in the first mask timer 6. 1 voltage detection circuit 5, a second mask timer 8 that outputs a signal when a preset time elapses,
Second voltage detection circuit 7 that changes the output signal when the output voltage of the error amplifier 2 falls below a preset threshold value for a time longer than the time set in the mask timer 8 of FIG. 5 from the output of the second voltage detection circuit 7, OR circuit 9 for obtaining the logical sum, the latch circuit 10 which outputs an alarm signal and a reset signal based on the output of the OR circuit 9, and the triangular wave generation circuit 4 The pulse width conversion circuit 1 generates a pulse signal having a pulse width corresponding to the output voltage of the error amplifier 2 in synchronization with the triangular wave signal and outputs or stops the pulse signal based on the output signal of the latch circuit 10. It

Here, the pulse width conversion circuit 1 outputs a pulse signal having a pulse width corresponding to the output voltage of the error amplifier 2 in synchronization with the triangular wave signal from the triangular wave generation circuit 4 and a pulse width modulation circuit 1-b. And an output gate circuit 1-a that outputs or stops the pulse signal from the pulse width modulation circuit 1-b based on the output signal from the latch circuit 10.

Next, the operation of this embodiment will be described with reference to the timing chart of FIG. Here, the time preset in the first mask timer 6 is TH, and the second time is
The time preset in the mask timer 8 is set to TL. In addition, the threshold value in the first voltage detection circuit 5 is set to V
H, and the threshold value in the second voltage detection circuit 7 is VL.

.. When the power supply is turned on at time 0, the input voltage of the error amplifier 2 rises from 0 (V), and the output of the error amplifier 2 increases linearly until it reaches the voltage of the reference voltage source 3, that is, until time t2. To go.

The detection value of the second voltage detection circuit 7 is the time t.
The output voltage of the error amplifier 2 up to 1 is the second voltage detection circuit 7
However, since the set time TL in the second mask timer 8 is set longer than t1, the latch circuit 10 does not operate.

The pulse width modulation circuit 1-b outputs a pulse signal having a pulse width corresponding to the output voltage of the error amplifier 2 in synchronization with the triangular wave signal from the triangular wave generation circuit 4.

The output gate circuit 1-a is a latch circuit 10.
Does not operate, the pulse signal from the pulse width modulation circuit 1-b is output as it is.

That is, the pulse width conversion circuit 1 continues to output a pulse signal, and the output voltage rises to a stable point corresponding to the voltage of the reference voltage source 3.

[0021]. When the input voltage of the error amplifier 2 becomes equal to the voltage of the reference voltage source 3, the pulse width modulation circuit 1-b
Outputs a pulse signal with a narrow pulse width.

The output gate circuit 1-a is a latch circuit 10.
Does not operate, the pulse signal from the pulse width modulation circuit 1-b is output as it is.

That is, the pulse width conversion circuit 1 continues to output the pulse signal having the narrowed pulse width, and the output voltage corresponding to the voltage of the reference voltage source 3 is maintained.

[0024]. If the input voltage of the error amplifier 2 becomes lower than the voltage of the reference voltage source 3 at time t3 due to a sudden load change or the like, the second voltage detection circuit 7 outputs the second output voltage of the error amplifier 2 from the time t4. The second mask timer 8 is operated in order to fall below the threshold value VL in the voltage detection circuit 7. However, since the set time TL in the second mask timer 8 is set longer than the time between t4 and t5, the output signal of the second voltage detection circuit 7 does not change and the latch circuit 10 does not operate.

That is, the pulse width modulation circuit 1-b outputs a pulse signal having a pulse width corresponding to the output voltage of the error amplifier 2 in synchronization with the triangular wave signal from the triangular wave generation circuit 4.

Since the latch circuit 10 does not operate, the output gate circuit 1-a outputs the pulse signal from the pulse width modulation circuit 1-b as it is.

That is, the pulse width conversion circuit 1 continues to output a pulse signal, and the output voltage rises to a stable point corresponding to the voltage of the reference voltage source 3.

As described above, for a transient output fluctuation,
The pulse width conversion circuit 1 does not stop the output of the pulse signal.

.. When a disturbance or failure exceeding TL occurs at the time t7 and the input voltage of the error amplifier 2 becomes lower than the voltage of the reference voltage source 3, the second voltage detection circuit 7 causes the output voltage of the error amplifier 2 to become the second voltage. The second mask timer 8 is operated at the time point t7 ′ below the threshold value VL in the voltage detection circuit 7.

Even at time t8 (= t7 '+ TL), since the output voltage of the error amplifier 2 is below the threshold value VL of the second voltage detection circuit 7, the output signal of the second voltage detection circuit 7 is Becomes "high level", the latch circuit 10 operates, and the output of the pulse signal from the output gate circuit 1-a is stopped. At the same time, an alarm signal is sent from the latch circuit 10.

.. When the input voltage of the error amplifier 2 rises above the voltage of the reference voltage source 3 due to a sudden load change or the like at time t9, the first voltage detection circuit 5 determines that the output voltage of the error amplifier 2 is the first voltage at time t10. Threshold value VH in detection circuit 5
The first mask timer 6 is operated in order to exceed.
However, the set time T in the first mask timer 6
Since H is set larger than the time between t10 and t11, the output signal of the first voltage detection circuit 5 does not change and the latch circuit 10 does not operate.

However, the pulse width modulation circuit 1-b does not output a pulse signal because the output voltage of the error amplifier 2 is large. When the output voltage of the error amplifier 2 drops to a stable point corresponding to the voltage of the reference voltage source 3, the pulse signal is output again to maintain the output voltage.

Since the latch circuit 10 does not operate, the output gate circuit 1-a outputs the pulse signal from the pulse width modulation circuit 1-b as it is.

That is, the pulse width conversion circuit 1 stops outputting the pulse signal until the output voltage drops to a stable point corresponding to the voltage of the reference voltage source 3, and when the stable point is reached, outputs the pulse signal again.

.. When the disturbance or fault exceeding TH occurs at time t13 and the input voltage of the error amplifier 2 rises above the voltage of the reference voltage source 3, the first voltage detection circuit 5 outputs the first output voltage of the error amplifier 2 to the first voltage detection circuit 5. The first mask timer 6 is operated at the time point t14 when the voltage exceeds the threshold value VH in the voltage detection circuit 5.

Even at time t15 (= t13 + TH), the output voltage of the error amplifier 2 exceeds the threshold value VH of the first voltage detection circuit 5, so the output signal of the first voltage detection circuit 5 is " Then, the latch circuit 10 operates, and the output of the pulse signal from the output gate circuit 1-a is stopped. At the same time, an alarm signal is sent from the latch circuit 10.

[0037]

Since the present invention is constructed and functions as described above, according to this, it is possible to eliminate an excess / undervoltage detection circuit and a photocoupler for signal transmission other than the output voltage control circuit. It is possible to provide an unprecedented excellent power supply control circuit that can be downsized and integrated.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing an embodiment of the present invention.

FIG. 2 is a timing chart for explaining the operation of FIG.

FIG. 3 is a configuration diagram showing a conventional example.

[Explanation of symbols]

 1 pulse width conversion circuit 1-a output gate circuit 1-b pulse width modulation circuit 2 error amplifier 3 reference voltage source 4 triangular wave generation circuit 5 first voltage detection circuit 6 first mask timer 7 second voltage detection circuit 8 Second mask timer 9 OR circuit 10 Latch circuit

Claims (1)

[Claims] 1. A reference voltage source, an error amplifier that amplifies a difference between an input voltage and the reference voltage source, a triangular wave generation circuit that generates a triangular wave, and an output voltage of the error amplifier that is preset for a certain period of time or more. A first voltage detection circuit that outputs a signal when the output voltage of the error amplifier falls below a preset threshold value for a certain period of time, and A voltage detection circuit, an OR circuit for obtaining a logical sum of the output of the first voltage detection circuit and the output of the second voltage detection circuit, and a latch circuit for outputting a latch signal based on the output of the OR circuit. And generating a pulse signal having a pulse width corresponding to the output voltage of the error amplifier in synchronization with the triangular wave signal from the triangular wave generation circuit, and generating the pulse signal based on the output signal of the latch circuit. The power supply control circuit is equipped with a pulse width conversion circuit that outputs or stops the signal.