JP2007317239A - Direct current power supply unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a direct current power supply unit of a simple circuit structure, capable of operating two power supply circuits by exclusively switching according to current consumption in a load. <P>SOLUTION: Between an input terminal IN and an output terminal OUT, there are connected in parallel a first power supply circuit 2 which is efficient when supplying power to a light load being a load of small current consumption, and a second power supply circuit 3 which is efficient when supplying power to a heavy load being a load of large current consumption, while efficiency is decreased when supplying power to a light load. By detecting the output voltage of the second power supply circuit 3, the first power supply circuit 2 controls whether or not voltage is to be output to the output terminal OUT. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a DC power supply apparatus with low current consumption, which can make output voltage constant at a predetermined voltage in response to fluctuations in output current and fluctuations in input voltage at high speed.

  In recent years, electric appliances have been required to save power in consideration of environmental problems. This tendency is particularly noticeable in battery-powered equipment. In general, as means for reducing power consumption, it is important to reduce the power consumed by the device and to improve the efficiency of the power supply itself to suppress wasteful power consumption. As one method for reducing the power consumed by a device, a state in which the device is not in operation is set to a standby state, and circuit operation in the device is stopped to reduce power consumption. However, even if the device shifts to the standby state, if the efficiency of the power supply circuit itself is poor, a sufficient power saving effect cannot be expected.

On the other hand, general power supply circuits used in equipment include a switching regulator and a series regulator.
Switching regulators have high efficiency at rated loads, but output voltage ripple and noise during operation are large, and internal power consumption is relatively large, so efficiency is high when power is supplied to light loads with low current consumption. It drops significantly. Furthermore, since the respective responses to the rise of the output voltage, the input voltage fluctuation, and the load fluctuation are somewhat slow, there is a drawback that the stability of the output voltage is low.

  On the other hand, the series regulator, when supplying power to a heavy load with large current consumption, consumes a large amount of power in the output control transistor, so the efficiency is low, but the output voltage ripple is small and the noise during operation is small. In addition, since the power consumed in the power supply control circuit can be reduced, the efficiency may be higher than that of the switching regulator when the load current is small. Furthermore, it is easy to speed up the response to rising of the output voltage, input voltage fluctuation, and load fluctuation, and the stability of the output voltage is high.

  Therefore, there has been a power supply device that can improve the efficiency of the power supply circuit itself by providing both of these two types of regulators and using only one of the regulators according to the load current ( For example, see Patent Document 1.)

FIG. 7 shows such a conventional power supply device.
In FIG. 7, the DC-DC converter 66 includes a series power supply circuit 100 and a switching power supply circuit 102. The series power supply circuit 100 has a power conversion efficiency of about 70% regardless of the load current, and is almost constant. The switching power supply circuit 102 has an efficiency of 80% or more in a heavy load with a large current consumption. As the light load becomes smaller, the efficiency decreases. The series power supply circuit 100 is operated in a light load, and the switching power supply circuit 102 is operated in a heavy load.

The PWM controllers 108 of the series power supply circuit 100 and the switching power supply circuit 102 are each provided with an enable terminal (-EN). When the enable terminal becomes low level and becomes active, each power supply circuit is set in advance. The specified voltages are output respectively. That is, in the case of a heavy load, the standby signal input to the input terminal 109 is set to a low level to activate the switching power supply circuit 102 and stop the operation of the series power supply circuit 100. In the case of a light load, the standby signal is set to a high level to stop the operation of the switching power supply circuit 102 and bring the series power supply circuit 100 into an operating state. In this way, when the load is light, the series power supply circuit 100 is used in place of the switching power supply circuit 102 whose efficiency has been reduced, and therefore the efficiency of the entire power supply circuit can be increased.
JP 2001-197731 A

  However, in FIG. 7, both the series power supply circuit 100 and the switching power supply circuit 102 are provided with an enable terminal, and each power supply circuit processes a signal input to the enable terminal in order to switch between operation and non-operation. Therefore, the circuit scale is increased, and a circuit for supplying an enable signal to each power supply circuit is required. Further, when the standby signal changes from low level to high level, even if the output voltage of the switching power supply circuit 102 decreases, it takes time for the output of the series power supply circuit 100 to rise to a specified voltage. There may be a problem that an undershoot occurs in which the common output terminal voltage drops momentarily.

  The present invention has been made to solve such a problem, and enables the operation and non-operation of two power supply circuits to be controlled only by outputting an enable signal to only one power supply circuit. Thus, it is an object to obtain a DC power supply device that can switch and operate two different power supply circuits exclusively in accordance with the current consumption of the load with a simple circuit configuration.

A DC power supply device according to the present invention is a DC power supply device that converts a voltage from a DC power supply into a predetermined voltage and outputs the voltage from an output terminal.
A first power supply circuit that converts a voltage from the DC power source into a predetermined first voltage and outputs the first voltage to the output terminal;
A second power supply circuit that is turned on and off by an external control signal that converts the voltage from the DC power source into a predetermined second voltage and outputs the second voltage to the output terminal;
With
The first power supply circuit detects the voltage of the output terminal when the second power supply circuit is turned off and outputs the first voltage.

  Specifically, the first power supply circuit controls the current output to the output terminal so that the detected voltage becomes the first voltage, and the first voltage is less than the second voltage.

The first power supply circuit includes:
A first reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr1;
A first voltage dividing circuit that divides and outputs the voltage of the output terminal;
An output control transistor that performs output control of a current supplied from the DC power supply according to an input control signal;
A first operational amplifier that controls the operation of the output control transistor so that the divided voltage Vd1 from the first voltage dividing circuit unit becomes the reference voltage Vr1;
It was made to be a series regulator with

Meanwhile, the second power supply circuit includes:
A second reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr2,
A second voltage dividing circuit for dividing and outputting the voltage of the output terminal;
A switching transistor that performs switching to output an input voltage from the DC power supply in response to an input control signal;
A second operational amplifier that amplifies a differential voltage between the reference voltage Vr2 and the divided voltage Vd2 from the second voltage dividing circuit unit;
The operation is performed or stopped according to the input control signal, and when the operation is performed, the switching transistor is controlled according to the output signal from the second operational amplifier, and when the operation is stopped, the switching transistor is turned off and shut off. A control circuit unit to be in a state;
A smoothing circuit unit that smoothes an output signal from the switching transistor and outputs the smoothed signal to the output terminal;
The switching regulator may be provided.

The second power supply circuit includes:
A third reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr3;
A third voltage dividing circuit for dividing and outputting the voltage of the output terminal;
An output control transistor that performs output control of a current supplied from the DC power supply according to an input control signal;
A third operational amplifier that controls the operation of the output control transistor so that the divided voltage Vd3 from the third voltage dividing circuit unit becomes the reference voltage Vr3;
It may be a series regulator provided with.

  Specifically, the first power supply circuit and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. I did it.

  The first power supply circuit and the second reference voltage generating circuit unit, the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. You may do it.

  On the other hand, the smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, the first power supply circuit, and a second reference voltage generation circuit unit in the second power supply circuit, The transistors of the second voltage dividing circuit unit, the second operational amplifier, the control circuit unit, and the smoothing circuit unit may be integrated into one IC.

  In addition, the smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, the first power supply circuit, and a second reference voltage generation circuit unit in the second power supply circuit, The transistors of the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, the control circuit unit, and the smoothing circuit unit may be integrated in one IC.

  A switching element connected between the output terminal of the first power supply circuit that outputs the first voltage and the output terminal, and the switching element receives a second voltage from the second power supply circuit; While it was, it was turned off and shut off.

  Specifically, the switching element is a diode connected so that a direction from the output terminal of the first power supply circuit to the output terminal is a forward direction.

  The first power supply circuit, the switching element, and the second reference voltage generating circuit unit, the second voltage dividing circuit unit, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. I did it.

  The first power supply circuit, the switching element, and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated into one IC. You may make it accumulate.

  Meanwhile, the smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, and generates a second reference voltage in the first power supply circuit, the switching element, and the second power supply circuit. The transistors of the circuit unit, the second voltage dividing circuit unit, the second operational amplifier, the control circuit unit, and the smoothing circuit unit may be integrated in one IC.

  The smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, and generates a second reference voltage in the first power circuit, the switching element, and the second power circuit. The transistors of the circuit unit, the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, the control circuit unit, and the smoothing circuit unit may be integrated into one IC.

  According to the DC power supply device of the present invention, the power supply circuit to be supplied to the load can be switched to either the first power supply circuit or the second power supply circuit simply by inputting a control signal to the second power supply circuit. A circuit for supplying a control signal to the first power supply circuit and a control signal processing circuit for the first power supply circuit are not required, and the circuit can be simplified and miniaturized, and the cost can be reduced.

  The first power supply circuit is a power supply circuit having high efficiency when supplying power to a light load, which is a load with low current consumption, for example, a series regulator, and the second power supply circuit 3 is a load with high current consumption. A power supply circuit that is highly efficient when power is supplied to a heavy load, but has a low efficiency when power is supplied to a light load, for example, a switching regulator. Since either one of the two power supply circuits is operated exclusively, it is possible to increase the power conversion efficiency and save power.

  Further, since the switching element is inserted between the output terminal of the first power supply circuit and the output terminal of the DC power supply device, the output voltage of the DC power supply device generated at the time of switching between the first power supply circuit and the second power supply circuit is reduced. Undershoot can be reduced, and the size of the capacitor connected to the output terminal can be reduced.

Next, the present invention will be described in detail based on the embodiments shown in the drawings.
First embodiment.
FIG. 1 is a block diagram showing a configuration example of a DC power supply device according to the first embodiment of the present invention.
In FIG. 1, a voltage Vbat from a DC power supply 7 such as a battery is input to an input terminal IN of the DC power supply apparatus 1, and a load 8 is connected to an output terminal OUT of the DC power supply apparatus 1. The DC power supply device 1 generates a predetermined constant voltage from the input voltage Vbat and outputs it to the load 8.

  The DC power supply device 1 generates a predetermined constant voltage Va from the input voltage Vbat and outputs it to the output terminal OUT, and generates and outputs a predetermined constant voltage Vb from the input voltage Vbat. A second power supply circuit 3 that outputs to a terminal OUT and a capacitor 4 are provided. A first power supply circuit 2 and a second power supply circuit 3 are connected in parallel between the input terminal IN and the output terminal OUT, and a capacitor 4 is connected between the output terminal OUT and the ground voltage.

  The first power supply circuit 2 is a high-efficiency power supply circuit when a constant voltage is supplied to a light load that is a load with low current consumption, and the second power supply circuit 3 is fixed to a heavy load that is a load with high current consumption. This is a power supply circuit that is highly efficient when supplying voltage, but decreases in efficiency when supplying a constant voltage to a light load. The first power supply circuit 2 detects the voltage Vo at the output terminal OUT and operates so that the voltage Vo becomes a predetermined constant voltage Va. In addition, when the second power supply circuit 3 does not output a voltage to the output terminal OUT, the first power supply circuit 2 detects that the voltage Vo of the output terminal OUT has decreased, and then outputs a predetermined constant to the output terminal OUT. The voltage Va is output.

  The second power supply circuit 3 operates in response to a control signal Sc input from the outside to the control signal input terminal. For example, when the control signal Sc is at a low level, the second power supply circuit 3 enters an operating state and generates a predetermined constant voltage Vb. Generate and output. In addition, when the control signal Sc is at a high (High) level, the second power supply circuit 3 is deactivated and deactivated, stops outputting the voltage to the output terminal OUT, and the second power supply circuit 3 itself Reduce power consumption to a level that consumes little power.

  As described above, the first power supply circuit 2 detects the output voltage of the second power supply circuit 3 and controls whether or not to output the voltage to the output terminal OUT. Does not require a control signal for switching between operation and non-operation. Therefore, the circuit scale can be reduced, and the size and cost can be reduced. The capacitor 4 is used to remove ripples from the output voltages from the first power supply circuit 2 and the second power supply circuit 3 and to respond to the fluctuations in the output current to the load 8 by the first power supply circuit 2 and the second power supply circuit 3. It has the function of suppressing fluctuations in the output voltage Vo due to delay. Further, the capacitor 4 does not cause an undershoot in the output voltage Vo until the second power supply circuit 3 is deactivated, the output voltage Vo is lowered, and the voltage is output from the first power supply circuit 2. Thus, it also has a function of holding the output voltage Vo.

FIG. 2 is a circuit diagram showing a circuit example of the first power supply circuit 2.
The first power supply circuit 2 in FIG. 2 includes a reference voltage generation circuit unit 11 that generates and outputs a predetermined reference voltage Vr1, and a voltage dividing circuit unit 14 that includes resistors 12 and 13 that divide and output the output voltage Vo. The output control transistor 15 including a P-channel MOS transistor (hereinafter referred to as a PMOS transistor) that outputs a current corresponding to the voltage input to the gate to the output terminal OUT, and the voltage generated by the voltage dividing circuit unit 14 The operational amplifier 16 controls the operation of the output control transistor 15 so that the voltage Vd1 becomes the reference voltage Vr1.

  The output voltage Vo is divided by the voltage dividing circuit unit 14, and a differential voltage between the divided voltage Vd 1 and the reference voltage Vr 1 is amplified by the operational amplifier 16 and output to the gate of the output control transistor 15. In this way, the operational amplifier 16 controls the operation of the output control transistor 15 so that the output voltage Vo becomes constant at a desired voltage. The reference voltage generating circuit unit 11 is a first reference voltage generating circuit unit, the voltage dividing circuit unit 14 is a first voltage dividing circuit unit, and the operational amplifier 16 is a first operational amplifier.

FIG. 3 is a circuit diagram showing a circuit example of the second power supply circuit 3.
The second power supply circuit 3 in FIG. 3 smoothes the output signal from the switching transistor 21 composed of a PMOS transistor that performs switching for outputting the voltage Vbat input from the DC power supply 7 and outputs it to the output terminal OUT. And a smoothing circuit unit 22 for outputting.

  Further, the second power supply circuit 3 divides the voltage Vo output from the output terminal OUT by generating a reference voltage generation circuit unit 23 that generates and outputs a predetermined reference voltage Vr2, and generates and outputs a divided voltage Vd2. A voltage dividing circuit unit 26 including resistors 24 and 25, an operational amplifier 27 that amplifies and outputs a difference voltage of the divided voltage Vd2 with respect to the reference voltage Vr2, and the switching transistor 21 according to an output signal from the operational amplifier 27 And a control circuit unit 28 for performing the switching control. The reference voltage generation circuit unit 23 forms a second reference voltage generation circuit unit, the voltage division circuit unit 26 forms a second voltage division circuit unit, and the operational amplifier 27 forms a second operational amplifier.

  The output voltage Vo is divided by the voltage dividing circuit unit 26, and a differential voltage between the divided voltage Vd2 and the reference voltage Vr2 is amplified by the operational amplifier 27. A control signal Sc is input to the operational amplifier 27 and the control circuit unit 28. The operational amplifier 27 and the control circuit unit 28 are activated when the control signal Sc is at a low level, and the control signal Sc is at a high level. In this case, the operation is stopped and the switching transistor 21 is turned off to be cut off, so that the output of the voltage to the output terminal OUT is stopped, and the power consumption of the second power supply circuit 3 itself is reduced to such an extent that it is hardly consumed. To do.

  The control circuit unit 28 includes, for example, an oscillation circuit that generates a triangular wave pulse signal and a comparator. The comparator compares the voltages of the output signal of the oscillation circuit and the output signal of the operational amplifier 27 with the comparator. The on-time of the switching transistor 21 is controlled according to the result. The signal output from the switching transistor 21 is smoothed by the smoothing circuit unit 22 including the diode D1 that forms a flywheel diode, the coil L1, and the capacitor C1, and is output to the output terminal OUT.

  In such a configuration, the output voltage Vo1 of the first power supply circuit 2 is set to be slightly smaller than the output voltage Vo2 of the second power supply circuit 3. For example, the first power supply circuit 2 and the second power supply circuit 3 are set so that the output voltage Vo1 is 1.8V and the output voltage Vo2 is 1.9V. Here, when the control signal Sc is at a low level, the second power supply circuit 3 operates, and the output voltage Vo2 and the voltage Vo of the output terminal OUT are 1.9V, respectively. On the other hand, in the first power supply circuit 2, feedback acts so as to lower the output voltage Vo to 1.8 V, and the operational amplifier 16 raises the gate voltage of the output control transistor 15. However, since the output voltage Vo is fixed at the output voltage 1.9 V of the second power supply circuit 3, the operational amplifier 16 turns off the output control transistor 15, and the voltage output from the first power supply circuit 2 is stopped. To do.

  Next, when the control signal Sc becomes high level, the second power supply circuit 3 becomes inoperative, the voltage output from the second power supply circuit 3 to the output terminal OUT is stopped, and the voltage of the output terminal OUT decreases. When the voltage at the output terminal OUT decreases to less than 1.8V, the feedback loop of the first power supply circuit 2 functions, and the first power supply circuit 2 fixes the voltage Vo at the output terminal OUT at 1.8V. In this way, a special control input terminal is added to the first power supply circuit 2 by setting the output voltage Vo1 of the first power supply circuit 2 to be slightly smaller than the output voltage Vo2 of the second power supply circuit 3. Without this, output control of the output voltage in the first power supply circuit 2 can be performed.

  1 to 3, the reference voltage generation circuit unit 23, the voltage dividing circuit unit 26, the operational amplifier 27, and the control circuit unit 28 of the first power supply circuit 2 and the second power supply circuit 3 are integrated in one IC. In some cases, the switching transistor 21 may be integrated in one IC. Further, an NMOS transistor 31 may be used instead of the diode D1 in FIG. 3, and in this case, the second power supply circuit 3 in FIG. 3 becomes as shown in FIG. In FIG. 4, the same components as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted. Also, it is known to use the NMOS transistor 31 whose operation is controlled by the control circuit unit 28 instead of the flywheel diode, and the description of the operation is omitted here. In the case of FIG. 4, the first power supply circuit 2, the reference voltage generating circuit unit 23, the voltage dividing circuit unit 26, the operational amplifier 27, the control circuit unit 28, and the NMOS transistor 31 can be integrated in one IC. In some cases, the switching transistor 21 may be integrated into one IC.

Meanwhile, in the above description, the case where the second power supply circuit 3 is a switching regulator has been described as an example. However, the second power supply circuit 3 may be a series regulator, and in this case, the second power supply circuit 3 in FIG. As shown in FIG.
In FIG. 5, the second power supply circuit 3 includes a reference voltage generating circuit unit 35 that generates and outputs a predetermined reference voltage Vr3, and a voltage dividing circuit unit 38 that includes resistors 36 and 37 that divide and output the output voltage Vo. And an output control transistor 39 and an operational amplifier 40 for controlling the operation of the output control transistor 39 so that the divided voltage Vd3 generated by the voltage dividing circuit unit 38 becomes the reference voltage Vr3. . The reference voltage generating circuit unit 35 is a third reference voltage generating circuit unit, the voltage dividing circuit unit 38 is a third voltage dividing circuit unit, and the operational amplifier 40 is a third operational amplifier.

The output voltage Vo is divided by the voltage dividing circuit unit 38, and a differential voltage between the divided voltage Vd3 and the reference voltage Vr3 is amplified by the operational amplifier 40 and output to the gate of the output control transistor 39. In this way, the operational amplifier 40 controls the operation of the output control transistor 39 so that the output voltage Vo is constant at a desired voltage. A control signal Sc is input to the operational amplifier 40. The operational amplifier 40 is activated when the control signal Sc is at a low level, and is deactivated when the control signal Sc is at a high level. The control transistor 39 is turned off to be cut off, stopping the output of the voltage to the output terminal OUT, and reducing the power consumption of the second power supply circuit 3 to such an extent that it hardly consumes.
When the second power supply circuit 3 having such a configuration is used, the first power supply circuit 2 and the second power supply circuit 3 may be integrated into one IC.

  As described above, the DC power supply according to the first embodiment is the first power supply circuit 2 that has high efficiency when supplying power to a light load that is a load with low current consumption, and a load with high current consumption. A second power supply circuit 3 is connected in parallel between the input terminal IN and the output terminal OUT, which is highly efficient when supplying power to a heavy load, but decreases in efficiency when supplying power to a light load. The first power supply circuit 2 detects the output voltage of the second power supply circuit 3 and controls whether or not to output the voltage to the output terminal OUT. This eliminates the need for a control signal for switching the operation between the first power supply circuit 2 and the first power supply circuit 2, thereby reducing the circuit scale and reducing the size and cost.

Second embodiment.
In the first embodiment, while the predetermined voltage is output from the second power supply circuit 3, the output control transistor 15 of the first power supply circuit 2 is turned off to be in the cut-off state. A switching element is provided between the power supply circuit 2 and the output terminal OUT, and while the predetermined voltage is output from the second power supply circuit 3, the switching element is turned off to be in a cut-off state. While the predetermined voltage is not output, the switching element may be turned on so that the output voltage of the first power supply circuit 2 is output to the output terminal OUT. The embodiment is as follows.

FIG. 6 is a block diagram showing a configuration example of a DC power supply device according to the second embodiment of the present invention. In FIG. 6, the same components as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted here, and only differences from FIG. 1 will be described.
6 is different from FIG. 1 in that a diode 45 serving as a switching element is provided between the output terminal of the first power supply circuit 2 and the output terminal OUT. Accordingly, the DC power supply device 1 in FIG. 1 is changed to a DC power supply device 1a.
The DC power supply device 1 a includes a first power supply circuit 2, a second power supply circuit 3, a capacitor 4, and a diode 45. A series circuit of the first power circuit 2 and the diode 45 and the second power circuit 3 are connected in parallel between the input terminal IN and the output terminal OUT, and a capacitor is connected between the output terminal OUT and the ground voltage. 4 is connected.

In such a configuration, the case where the output voltage Vo2 of the second power supply circuit 3 is set to 1.9 V will be described as an example.
When the control signal Sc is at a low level, the second power supply circuit 3 is activated, and the voltage Vo at the output terminal OUT is 1.9V. In addition, the voltage is output from the first power supply circuit 2, but the output voltage Vo1 is less than or equal to the value obtained by adding the forward voltage Vth (= about 0.6V) of the diode 45 to the voltage Vo (= 1.9V). If so, the output voltage Vo1 is not output to the output terminal OUT. For example, when the output voltage Vo1 is set to 2.4V, the output voltage Vo1 is not output to the output terminal OUT while the second power supply circuit 3 is operating.

  Next, when the control signal Sc becomes high level, the second power supply circuit 3 becomes inoperative and the output voltage Vo decreases. When the voltage Vo at the output terminal OUT becomes less than 1.8 V, the diode 45 becomes forward biased and the output voltage Vo1 is output to the output terminal OUT. By using a diode having a small threshold voltage Vth, such as a Schottky barrier diode, for the diode 45, the power supply efficiency can be increased by the amount that the forward voltage of the diode 45 is reduced.

  In FIG. 6, the first power supply circuit 2, the diode 45, and the reference voltage generation circuit unit 23, the voltage dividing circuit unit 26, the operational amplifier 27, and the control circuit unit 28 of the second power supply circuit 3 are integrated in one IC. In some cases, the switching transistor 21 of the second power supply circuit 3 may be integrated into one IC. As in the case shown in FIG. 4, the NMOS transistor 31 may be used instead of the diode D <b> 1 of the second power supply circuit 3. In this case, the first power supply circuit 2, the diode 45, the reference voltage generating circuit unit 23, the voltage dividing circuit unit 26, the operational amplifier 27, the control circuit unit 28, and the NMOS transistor 31 can be integrated in one IC. In some cases, the switching transistor 21 may be integrated into one IC.

  On the other hand, as in the case shown in FIG. 5, the second power supply circuit 3 may be a series regulator. In this case, the first power supply circuit 2, the diode 45, and the second power supply circuit 3 are 1 in number. You may make it integrate on one IC.

  As described above, in the DC power supply device according to the second embodiment, the voltage Vo1 output from the first power supply circuit 2 to the output terminal OUT while the second power supply circuit 3 is not operating is used. By setting the second power supply circuit 3 to be smaller than the voltage Vo2 output to the output terminal OUT, the output voltage of the first power supply circuit 2 is not added to the first power supply circuit 2 without adding a special control input terminal. The output / non-output of Vo1 can be controlled.

  Further, even when the second power supply circuit 3 is in operation, the first power supply circuit 2 always generates and outputs the output voltage Vo1, so that the second power supply circuit 3 becomes inoperative and the first power supply circuit 2 can suppress the undershoot generated in the output voltage Vo as described in the first embodiment even at the changing point where the voltage Vo1 is output from the output terminal OUT to the output terminal OUT, and is connected to the load 8 in parallel. The capacity of the capacitor 4 can be reduced.

  In the first and second embodiments, the case where a PMOS transistor is used as the control element has been described as an example. However, instead of the PMOS transistor, an N-channel MOS transistor or a junction type field effect is used. A transistor may be used, and it is also possible to use a bipolar PNP transistor or NPN transistor.

It is the block diagram which showed the structural example of the DC power supply device in the 1st Embodiment of this invention. FIG. 2 is a circuit diagram illustrating a circuit example of a first power supply circuit 2 in FIG. 1. FIG. 2 is a circuit diagram illustrating a circuit example of a second power supply circuit 3 in FIG. 1. FIG. 6 is a circuit diagram illustrating another circuit example of the second power supply circuit 3 in FIG. 1. FIG. 6 is a circuit diagram illustrating another circuit example of the second power supply circuit 3 in FIG. 1. It is the block diagram which showed the structural example of the DC power supply device in the 2nd Embodiment of this invention. It is the block diagram which showed the structural example of the conventional DC power supply device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,1a DC power supply device 2 1st power supply circuit 3 2nd power supply circuit 4 Capacitor 7 DC power supply 8 Load 11, 23, 35 Reference voltage generation circuit part 14, 26, 38 Voltage dividing circuit part 15, 39 Output control transistor 16 27, 40 Operational amplifier 21 Switching transistor 22 Smoothing circuit section 28 Control circuit section 45 Diode

Claims (15)

In the DC power supply device that converts the voltage from the DC power supply to a predetermined voltage and outputs it from the output terminal,
A first power supply circuit that converts a voltage from the DC power source into a predetermined first voltage and outputs the first voltage to the output terminal;
A second power supply circuit that is turned on and off by an external control signal that converts the voltage from the DC power source into a predetermined second voltage and outputs the second voltage to the output terminal;
With
The DC power supply device, wherein the first power supply circuit detects the voltage of the output terminal when the second power supply circuit is turned off and outputs the first voltage.   2. The first power supply circuit controls a current output to the output terminal so that the detected voltage becomes a first voltage, and the first voltage is less than the second voltage. DC power supply. The first power supply circuit includes:
A first reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr1;
A first voltage dividing circuit that divides and outputs the voltage of the output terminal;
An output control transistor that performs output control of a current supplied from the DC power supply according to an input control signal;
A first operational amplifier that controls the operation of the output control transistor so that the divided voltage Vd1 from the first voltage dividing circuit unit becomes the reference voltage Vr1;
The DC power supply device according to claim 1, wherein the DC power supply device is a series regulator comprising: The second power supply circuit includes:
A second reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr2,
A second voltage dividing circuit for dividing and outputting the voltage of the output terminal;
A switching transistor that performs switching to output an input voltage from the DC power supply in response to an input control signal;
A second operational amplifier that amplifies a differential voltage between the reference voltage Vr2 and the divided voltage Vd2 from the second voltage dividing circuit unit;
The operation is performed or stopped according to the input control signal, and when the operation is performed, the switching transistor is controlled according to the output signal from the second operational amplifier, and when the operation is stopped, the switching transistor is turned off and shut off. A control circuit unit to be in a state;
A smoothing circuit unit that smoothes an output signal from the switching transistor and outputs the smoothed signal to the output terminal;
4. A DC power supply device according to claim 1, wherein the DC power supply device comprises a switching regulator. The second power supply circuit includes:
A third reference voltage generation circuit unit that generates and outputs a predetermined reference voltage Vr3;
A third voltage dividing circuit for dividing and outputting the voltage of the output terminal;
An output control transistor that performs output control of a current supplied from the DC power supply according to an input control signal;
A third operational amplifier that controls the operation of the output control transistor so that the divided voltage Vd3 from the third voltage dividing circuit unit becomes the reference voltage Vr3;
4. The DC power supply device according to claim 1, wherein the DC power supply device is a series regulator.   The first power supply circuit, and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. The DC power supply device according to claim 4.   The first power supply circuit and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. 5. The DC power supply device according to claim 4, wherein   The smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, the first power supply circuit, a second reference voltage generation circuit unit in the second power supply circuit, a second 5. The DC power supply device according to claim 4, wherein the transistors of the voltage dividing circuit unit, the second operational amplifier, the control circuit unit, and the smoothing circuit unit are integrated in one IC.   The smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode, the first power supply circuit, a second reference voltage generation circuit unit in the second power supply circuit, a second 5. The DC power supply device according to claim 4, wherein the transistors of the voltage dividing circuit unit, the switching transistor, the second operational amplifier, the control circuit unit, and the smoothing circuit unit are integrated in one IC.   A switching element connected between the output terminal of the first power supply circuit that outputs the first voltage and the output terminal, and the switching element outputs a second voltage from the second power supply circuit; 6. The DC power supply device according to claim 1, wherein the DC power supply device is turned off to be cut off.   The DC power supply device according to claim 10, wherein the switching element is a diode connected so that a direction from the output terminal of the first power supply circuit to the output terminal is a forward direction.   The first power supply circuit, the switching element, and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. The DC power supply device according to claim 10 or 11, characterized in that   The first power supply circuit, the switching element, and the second reference voltage generation circuit unit, the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, and the control circuit unit in the second power supply circuit are integrated in one IC. The DC power supply device according to claim 10 or 11, wherein:   The smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode. The first power supply circuit, the switching element, and a second reference voltage generation circuit unit in the second power supply circuit 12. The DC power supply device according to claim 10, wherein the transistors of the second voltage dividing circuit unit, the second operational amplifier, the control circuit unit, and the smoothing circuit unit are integrated in one IC.   The smoothing circuit unit includes a transistor whose operation is controlled by the control circuit unit and performs the same function as a flywheel diode. The first power supply circuit, the switching element, and a second reference voltage generation circuit unit in the second power supply circuit 12. The DC power supply device according to claim 10, wherein the transistors of the second voltage dividing circuit unit, the switching transistor, the second operational amplifier, the control circuit unit, and the smoothing circuit unit are integrated in one IC. .

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