JP2880108B2 - Power supply control device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a plurality of switching power supply circuits having different characteristics (specifically, a normal rectification type and a synchronous rectification type switching power supply circuit) provided in a power supply device. The present invention relates to a power supply control device having a master / slave function for causing each switching power supply circuit to perform an independent control operation while synchronizing operation timing as a whole.

[0002]

2. Description of the Related Art In recent years, electronic devices have been improved in performance and multi-functionality while being small in size, and a power supply device incorporated in the electronic devices has a plurality of power supplies according to loads (machines and circuits) having different characteristics. It has a switching power supply circuit. Here, a pulse width modulation type control integrated circuit (PWM control IC) is generally used for drive control of the switching power supply circuit, and has a number of control systems corresponding to a load or a power supply circuit. When a plurality of switching power supply circuits are independently operated in the same power supply device, an interference phenomenon (switching beat) based on a plurality of switching operations may occur in the device. This, for example, when two switching power supply circuits, each of which to be operating in the switching frequencies f ₁ and f _2, that the low frequency corresponding to the difference between two switching frequencies (f ₁ -f ₂₎ is generated Is due.

In a conventional power supply device, in order to prevent the occurrence of the switching beat, the timing and frequency of the switching operation of a switching power supply circuit that operates independently are synchronized with each other. As an example of this, a plurality of control devices provided to drive and control each switching power supply circuit are used as a master device.
It has a slave function, one of which operates as a master control device at an independent operation timing and a pulse frequency set in advance by a circuit, and the other as a slave control device, receives a synchronization signal from the master side, There is a means for operating at the same oscillation frequency as the operation timing synchronized with the side control device.
FIG. 6 schematically illustrates a power supply control device configured to prevent the occurrence of such switching beats and a power supply device having the same.

In FIG. 6, two switching power supply units PS1 and PS2 are connected to control units CD1 and CD1, respectively.
2 is independently driven and controlled. Here the control device CD
1 includes a control system including an error amplifier Err1, a comparator Comp1, and an output buffer Buf1, a reference voltage source 11 for supplying various signals to the control system, an oscillation circuit 12, and an accessory circuit 13. As an operation of the control device CD1, first, a feedback signal (FB1) is received from the switching power supply circuit PS1, and an error amplifier Er is received.
At r1, an error signal is obtained by comparison with the reference voltage (V _REF ). The error signal is compared with the triangular wave voltage (reference waveform signal) from the oscillation circuit 12 in the comparator Comp1, and an on-duty pulse output signal (PO
1) is generated. This pulse output signal (PO1) is supplied to the switching element of the switching power supply circuit via the output buffer Buf1, whereby the switching power supply circuit PS1 is driven and controlled so that the output voltage becomes constant.

Here, the accessory circuit 13 outputs an operation stop signal when an abnormality occurs in the switching power supply circuit PS1, and the output buffer Buf1 receives the operation stop signal and prohibits the passage of the pulse output signal (PO1).
The operation of the switching power supply circuit PS1 is stopped. The oscillation circuit 12 supplies a triangular wave voltage to the comparator Comp1 and simultaneously outputs a synchronization signal (RSS) (generally, the same voltage signal as the triangular wave voltage supplied to the comparator Comp1) to the outside. .

The control device CD2 includes an error amplifier Err
2. A control system including a comparator Comp2 and an output buffer Buf2, and a reference voltage source 2 for supplying various signals to the control system
1, an oscillation circuit 22 and an accessory circuit 23. The operation of the control device CD2 is basically the same as that of the control device 1, except that the oscillation circuit 12 of the control device CD1 generates a triangular wave voltage with independent operation timing and a preset pulse frequency. On the other hand, in the control device CD2, the oscillation circuit 22 receives the synchronization signal (RSS) from the control device CD1, and is different from the oscillation circuit 12 in that the operation timing and the oscillation frequency operate so as to generate the same triangular wave voltage. . As can be seen from this, in FIG. 6, the control device CD1 functions as a master-side control device, and the control device CD2 functions as a slave-side control device.

[0007] In recent years, there has been a strong demand for downsizing of the power supply device due to the recent portable electronic devices. In reducing the size of the power supply device, the switching frequency of the switching element is increased for the purpose of reducing the inductance and the capacitor, which are components of the switching power supply circuits (PS1, PS2). The switching frequency is determined by the oscillation frequency of the triangular wave voltage output from the oscillation circuit (12, 22) of the control device (CD1, CD2). The commonly used oscillation frequency is several hundred [kHz]. At present, there are several [MHz]. On the other hand, when an electronic device is made portable, a battery is used as a power supply source, and thus there is a strong demand for a power supply device with low power consumption. To reduce the power consumption of the power supply device, it is necessary to improve the efficiency of each switching power supply circuit, and a synchronous rectification method may be employed as a means for improving the efficiency of the switching power supply circuit.

In this synchronous rectification system, the loss caused by the on-state collector-emitter voltage generated in the transistor is smaller than the loss caused by the forward drop voltage generated in the diode. The generated loss is reduced, and the efficiency of the switching power supply circuit can be improved. However, in practice, when a transistor is used as a rectifying element, a loss is involved in the on / off operation, and the loss increases rapidly as the switching frequency increases. As a result, depending on the switching frequency, the loss is smaller in the normal rectification method using a diode than in the synchronous rectification method using a transistor. Incidentally, in the current semiconductor device, in order to obtain the benefit of improving the efficiency of the switching power supply circuit by adopting the synchronous rectification method, the switching frequency is about 200 [kHz].
Is said to be the limit.

In the synchronous rectification method using a transistor as a rectifying element, it is necessary to drive the transistor as a rectifying element in a complementary manner in synchronization with the operation of a switching element, and further require circuits and parts for that. . Therefore, the switching power supply circuit employing the synchronous rectification system is larger in size than the case of employing the normal rectification system at the cost of improving the efficiency, and as a result, the size of the power supply device is increased.

[0010]

In order to achieve a good balance between miniaturization and high efficiency of a power supply device, for example, a switching power supply circuit of a normal rectification system is applied to a load with low power consumption to reduce the size. In order to achieve high efficiency by applying a synchronous rectification type switching power supply to a load that consumes a large amount of power, such as a normal rectification type and a synchronous rectification type switching power supply circuit according to the characteristics of the load. May be appropriately arranged. However, when the switching power supply circuit of the normal rectification method and the synchronous rectification method are actually used together, the power supply control devices (CD1, CD2) of the master-slave method as shown in FIG.
In order to prevent the occurrence of a switching beat, the master control device (CD1) and the slave control device (C
Since the operation timing of each triangular wave voltage of D2) is synchronized and the oscillation frequency is the same, the pulse frequency (= switching frequency) of the pulse output signal (PO) supplied from each control device to the switching power supply circuit is 1
The problem is that there is only one type.

That is, the switching frequency and high efficiency required for downsizing the switching power supply circuit (synchronous rectification)
Because of the contradictory conditions of the switching frequency required in the above, either one of miniaturization and high efficiency must be sacrificed after all. Therefore, in the present invention, a plurality of switching power supply circuits having different properties including the normal rectification method and the synchronous rectification method are controlled under the switching conditions suitable for each by the control devices provided respectively, while preventing the occurrence of the switching beat. An object of the present invention is to provide a power supply control device having a master / slave function, which can be operated, thereby achieving a good balance between miniaturization and high efficiency of the power supply device.

[0012]

According to the present invention, a pulse output signal is output at a preset pulse frequency by independent operation timing and a circuit, and at least one of a plurality of power supply circuits provided separately is independently controlled. Receives a synchronization signal from the master controller or the master controller, outputs a pulse output signal at the operation timing and pulse frequency synchronized with the master controller, and independently controls a power supply circuit different from the master to be used as a slave control device, the power supply control apparatus for a pulse width modulation scheme having a master-slave function, the frequency dividing means is provided, the pulse output signal output by the operation timing and frequency in accordance with the synchronization signal than, outputs a pulse output signal such that the low frequency of the pulse frequency (1 / n)
And it is characterized in the this <br/> that drives and controls the power supply circuit employing synchronous rectification.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In a first embodiment of the present invention, a frequency dividing circuit is provided on the output side of a comparing means for generating a pulse output signal in a slave side control device, and a master side control device outputs an output. The slave controller outputs a pulse output signal whose pulse frequency is a low frequency of (1 / n) with respect to the pulse output signal. As a second embodiment of the present invention, a frequency dividing means is added to an oscillation circuit for generating a reference waveform signal (triangular wave voltage) according to a synchronization signal in a slave side control device, and the master side control device outputs the frequency division means. The slave controller outputs a pulse output signal whose pulse frequency is a low frequency of (1 / n) with respect to the pulse output signal. As a third embodiment of the present invention,
A frequency dividing circuit is provided on the output side of the comparing means for generating a pulse output signal in the master-side control device, and the pulse frequency of the pulse output signal output from the slave-side control device by the synchronization signal supplied by itself is set to ( A pulse output signal having a low frequency of 1 / n) is output to the master-side control device.

According to a fourth embodiment of the present invention, there is provided an oscillation circuit for generating a reference waveform signal and a synchronizing signal at a pulse frequency preset by an independent operation timing and a circuit in a master-side control device. A frequency dividing means is added, and a pulse output signal whose pulse frequency is a low frequency of (1 / n) is output to the master side with respect to the pulse output signal output by the slave side control device with the synchronization signal supplied by itself. Output to the control device. According to a fifth embodiment of the present invention, there is provided an oscillator circuit for generating a reference waveform signal and a synchronizing signal at a pulse frequency preset by an independent operation timing and a circuit in a master-side control device. To generate a frequency-divided synchronizing signal in addition to the normal synchronizing signal, and to the slave-side control device that supplies the frequency-divided synchronizing signal, the pulse frequency is (1/1) than the pulse output signal output by itself. A pulse output signal having a low frequency of n) is output. In the first, second, and fifth embodiments, the master-side control device drives and controls the normal rectification-type switching power supply circuit, and the slave-side control device drives and controls the synchronous rectification-type switching power supply circuit.
In the third and fourth embodiments, the master control device controls the switching power supply circuit of the synchronous rectification system, and the slave control device controls the switching power supply circuit of the normal rectification system.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A master / slave function capable of operating a plurality of switching power supply circuits having different characteristics, such as a normal rectification system and a synchronous rectification system, under switching conditions suitable for each while preventing occurrence of switching beats. FIG. 1 schematically shows a power supply control apparatus according to a first embodiment of the present invention. In FIG. 1, the same components as those shown in FIG. 6 are denoted by the same reference numerals. The power supply control device CD2-a shown in FIG. 1 is a control device used as a slave side, and includes an error amplifier Er.
In contrast to a control system composed of r2, a comparator Comp2 and an output buffer Buf2, a frequency divider div1 is further provided on the output side of the comparator Comp2.

The frequency dividing circuit div1 has a comparator Comp.
2. The pulse frequency (= switching frequency) of the pulse output signal (PO2) generated in step 2 is divided, and the pulse output signal (PO1) output from the master-side control device (not shown) or the synchronization signal from the master is output. The pulse frequency is set to be lower than the pulse output signal output from another slave-side control device (not shown) whose operation timing and pulse frequency are matched exactly. The control device CD2-a of FIG. 1 in which the pulse output signal has a low frequency drives and controls the synchronous rectification type switching power supply circuit, and the normal rectification type switching power supply circuit uses a master side control device or the like in which the pulse output signal has a high frequency. Drive control,
In the same power supply device, the switching power supply circuit of the normal rectification type can easily achieve downsizing by increasing the switching frequency, and the switching power supply circuit of the synchronous rectification type can easily achieve higher efficiency by lowering the switching frequency. .

Since the low-frequency pulse output signal and the high-frequency pulse output signal have a multiplying pulse frequency and coincide with the operation timing, there is no need to worry about occurrence of a switching beat. In the control device CD2-a shown in FIG. 1, the frequency divider div1 is connected to the output terminal of the comparator Comp2 to divide the frequency of the pulse output signal (PO2) generated in the comparator Comp2. The output terminal of the comparator Comp2 may be connected to the output buffer Buf2, and the frequency divider circuit div1 may be connected to the output terminal of the output buffer Buf2.

FIG. 2 shows a second embodiment of the power supply control device according to the present invention. In the control device CD2-a shown in FIG. 1, the frequency dividing circuit div1 is provided on the output side of the comparator Comp2 as a component of the control system. However, in the control device shown in FIG. Frequency dividing means is added to the oscillation circuit 22a which outputs a triangular wave voltage at an operation timing and an oscillation frequency according to a signal. In this case, since the frequency of the triangular wave voltage input to the comparator Comp2 is reduced by the frequency dividing means, the pulse output signal (PO2) generated by the comparator Comp2.
Has a lower pulse frequency than the pulse frequency of the pulse output signal output from the master-side control device or another slave-side control device that operates faithfully with the synchronization signal from the master.

As a result, the control device CD2-a shown in FIG.
The control device CD2-b shown in FIG. 2 has the same function as the control device CD2-b, so that the size and efficiency of the power supply device can be reduced without difficulty, and there is no fear of generating a switching beat.
Note that there are various circuit systems for an oscillator circuit that outputs a triangular wave voltage. However, in many cases, a rectangular wave voltage is generated from a DC voltage and the rectangular wave voltage is converted into a triangular wave voltage. The addition form of the frequency dividing means in the oscillation circuit 22a shown in the embodiment of FIG. 2 differs depending on the circuit system and the synchronization signal received from the master, but includes a reception step of the synchronization signal, a generation step of the rectangular wave voltage, a triangular wave voltage. The frequency division may be performed at any stage of the conversion stage. Also, without dividing the frequency dividing means into the oscillation circuit, the frequency dividing circuit and the oscillation circuit are formed separately,
The frequency dividing circuit may be provided on the receiving side of the synchronization signal of the oscillation circuit or on the output side of the triangular wave voltage.

FIGS. 3, 4 and 5 show third, fourth and fifth embodiments of the power supply control device according to the present invention, respectively. In the control device shown in FIGS. 1 and 2 described above, the frequency divider circuit (means) is provided in the control device on the slave side. However, the control device shown in FIGS. Is provided with a frequency dividing circuit (means). The control device CD1-a of FIG. 3 is similar to the control device CD2-a of FIG.
1 is provided with a frequency dividing circuit div2 on the output side. The oscillation circuit 12 in FIG. 3 outputs a triangular wave voltage at an independent operation timing and a pulse frequency preset by the circuit, and the operation timing and frequency of the synchronizing signal (RSS) are naturally the same as this triangular wave voltage. It will be. Therefore, the pulse output signal generated by the comparator Comp1 in FIG. 3 and the pulse output signal output from the slave-side control device that operates in accordance with the synchronization signal have the same operation timing and pulse frequency.

However, in the control device CD1-a shown in FIG. 3, the frequency of the pulse output signal (PO1) appearing at the output terminal pin B is divided by the frequency dividing circuit div2, and the pulse output signal (PO1) is The frequency is lower than the pulse output signal output by the slave control device. The control device CD1-b of FIG.
Similarly to b, a frequency dividing means is added to the oscillation circuit 12a. Here, an oscillation circuit 22a to which frequency dividing means is added
Sets the frequency of the triangular wave voltage supplied to the comparator Comp1 to be lower than the frequency of the synchronization signal (RSS) supplied to the slave-side control device.
The pulse frequency of the pulse output signal (PO1) output from 1-b is lower than the pulse output signal output by the slave-side control device that operates in accordance with the synchronization signal (RSS).

On the other hand, in the control device CD1-c of FIG. 5, a frequency dividing means is added to the oscillation circuit 12b, and, contrary to FIG. 4, a synchronization signal (RSS) supplied to the slave control device.
Is lower than the frequency of the triangular wave voltage supplied to the comparator Comp1. The oscillation circuit 12 shown in FIG.
In b, assuming that a plurality of slave-side control devices exist and control devices corresponding to the normal rectification method and the synchronous rectification method are mixed, two synchronization signals of a high frequency and a low frequency are obtained. is there. In any of the control devices, a low-frequency pulse output signal by a frequency dividing circuit (means) is obtained in one of the master and slave control devices, and a high-frequency pulse output signal is obtained in the other control device. Accordingly, a control device (C in FIG. 3) in which the pulse output signal has a low frequency
D1-a, CD1-b in FIG. 4, slave side in FIG. 5) drives and controls a switching power supply circuit of the synchronous rectification system, and a pulse output signal becomes a high-frequency control device (slave side in FIGS. 3 and 4; By driving the switching power supply circuit of the normal rectification type in CD1-c) of No. 5, the power supply device can be reduced in size and increased in efficiency, and there is no fear of generating a switching beat.

In the above description of the embodiment, each control device is assumed to be a single-channel type having one control system. A control device having a system may be used. Some control devices for driving and controlling the switching power supply circuit of the synchronous rectification type include a component for supplying a pulse output signal to the main switching element and a signal having a phase opposite to that of the pulse output signal. There is also a component provided with a component to be supplied to the synchronous rectifier,
It goes without saying that the present invention can be applied to such a control device. However, when such a control device is provided with frequency dividing means on the output side of the comparator, the frequency dividing means may be required in a number corresponding to the number of output signals.

Further, in a power supply device having an unspecified number of power supply circuits, there may be a plurality of control devices provided with frequency dividing means as shown in FIGS. 1 and 2. In this case,
It is not necessary to make the dividing ratios of the respective dividing units the same, and the dividing ratios may be set according to the characteristics of the switching power supply circuit to be driven and controlled. The control device shown in FIGS. 1 and 2 and the control device shown in any of FIGS. 3 to 5 may be present simultaneously in one power supply device.

[0025]

As described above, in the power supply control device according to the present invention, the master side control device or the slave side control device is provided with frequency dividing means, and the operation timing of the pulse output signal output for each control device is controlled. While synchronizing, the pulse frequency of the pulse output signal is made different depending on the power supply circuit to be controlled. This makes it possible to drive and control a plurality of switching power supply circuits having different properties, for example, a normal rectification method and a synchronous rectification method, under switching conditions suitable for each, and furthermore, a switching beat is generated in the control device or the power supply device. It is prevented from occurring. As a result, by applying the control device according to the present invention, it is possible to achieve a good balance between miniaturization and high efficiency of the power supply device without sacrificing one of miniaturization and high efficiency.

[Brief description of the drawings]

FIG. 1 is a power supply control device (slave side) according to the present invention.
FIG. 2 is a circuit diagram of the first embodiment.

FIG. 2 is a power supply control device (slave side) according to the present invention.
FIG. 4 is a circuit diagram of a second embodiment of FIG.

FIG. 3 is a power supply control device (master side) according to the present invention.
FIG. 8 is a circuit diagram of a third embodiment.

FIG. 4 is a power supply control device (master side) according to the present invention.
FIG. 9 is a circuit diagram of a fourth embodiment.

FIG. 5 is a power supply control device (master side) according to the present invention.
FIG. 8 is a circuit diagram of a fifth embodiment.

FIG. 6 is a schematic diagram of a conventional power supply control device having a master / slave function and a power supply device to which the control device is applied.

[Explanation of symbols]

 CD1 Master-side control device CD2 Slave-side control device 12 Master-side oscillation circuit 22 Slave-side oscillation circuit 11, 21 Reference voltage source 13, 23 Accessory circuit PS1 Switching power supply circuit PS2 Switching power supply circuit div Divider circuit (PO1) Master-side pulse output Signal (PO2) Master side pulse output signal (RSS) Synchronization signal

Claims (7)

(57) [Claims] A master control device that outputs a pulse output signal at a pulse frequency set in advance by independent operation timing and a circuit and independently controls at least one of a plurality of power supply circuits provided together; or As a slave control device that receives a synchronization signal from the master control device, outputs a pulse output signal at an operation timing and a pulse frequency synchronized with the master control device, and independently controls a power supply circuit different from the master. used,
A pulse width modulation type power supply control device having a master / slave function, comprising a frequency dividing means, wherein the pulse frequency is lower than that of a pulse output signal output in accordance with the synchronization signal with a pulse frequency of (1 / n). outputs a pulse output signal as it is, synchronous rectification side
A control device for a power supply, characterized in that a power supply circuit employing a formula is driven and controlled . Receiving a synchronization signal supplied from the master control device, outputting a pulse output signal at an operation timing synchronized with the master control device, and independently controlling a power supply circuit different from the master. A pulse width modulation type power supply control device having a master / slave function, comprising a frequency dividing means, wherein the pulse frequency is lower than that of the pulse output signal output by the master control device by (1 / n). outputs a pulse output signal as it is, synchronous rectification
A control device for a power supply, wherein the power supply circuit employs a drive control . 3. A pulse output signal is output at a preset pulse frequency by independent operation timing and a circuit, and at least one of a plurality of power supply circuits provided independently is independently controlled, and another one for a slave is output. A pulse width modulation type power supply control device having a master / slave function, which supplies a synchronization signal for synchronizing operation timing to a control device, comprising: a slave having frequency dividing means and operating in accordance with the control signal Than the pulse output signal output by other control devices for
A power supply circuit that outputs a pulse output signal whose pulse frequency is as low as (1 / n) and employs a synchronous rectification method
A power supply control device for controlling driving of a road . 4. A pulse output signal is output at a preset pulse frequency by independent operation timing and a circuit, and at least one of a plurality of power supply circuits provided independently is independently controlled, and another one for a slave is provided. A pulse width modulation type power supply control device having a master / slave function for supplying a synchronization signal for synchronizing an operation timing to a control device. A synchronous rectification method is used for the synchronous signal for outputting a pulse output signal whose pulse frequency is lower than (1 / n).
A power supply control device for supplying a power supply circuit to a slave control device for driving the power supply circuit . 5. The method according to claim 1, wherein said frequency dividing means is provided on the output side of a comparing means for comparing an error signal corresponding to a deviation amount from a set value of the output voltage with a reference waveform signal to generate said pulse output signal. Claim 2 or Claim 3
The control device for a power supply described in 1. 6. The frequency dividing means according to claim 2, wherein said frequency dividing means is added to an oscillating means for supplying a reference waveform signal to a comparing means for generating said pulse output signal. 4. The control device for a power supply according to any one of 4. 7. A comparator for generating the pulse output signal.
Triangular wave power of the oscillating means for supplying a reference waveform signal to the
Characterized in that the frequency dividing means is provided on the pressure output side,
The power supply control device according to claim 2 or 3.