JPH09247936A - Switching power supply - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switching power supply whose circuit construction can be simplified. SOLUTION: The diode 10A of a switching circuit 10 opens the connection between a diode 4 and a capacitor 5 when a MOS-FET 6A is turned on and, further, the diode 10B of the switching circuit 10 connects the MOS-FET 6A to a detection circuit 8. With this process, the DC voltage of a terminal 104 is stabilized. When the MOS-FET 6A is turned off, the diode 10A connects the diode 4 to the capacitor 5 and, further, the diode 10B opens the connection between the MOS-FET 6A and the detection circuit 8 to apply the output of the capacitor 5 to the detection terminal 8D of the detection circuit 8. With this process, the DC voltage of a terminal 103 is stabilized.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a switching power supply device that generates a plurality of DC voltages from an input DC voltage.

[0002]

2. Description of the Related Art FIG. 3 shows a switching power supply device for generating a plurality of DC voltages from input DC. A DC voltage is applied between the terminals 211 and 212 of this switching power supply device.

The switching circuit 202 of the switching power supply device includes a MOS • FET 202A and a controller 20.
With 2B. The switching circuit 202 is the transformer 2
DC voltage applied to the primary side of 01
It is switched on and off at 202A and converted into alternating current. Controller 2
02B controls the connection and disconnection of the MOS • FET 202A.

Conversion circuit 203 of switching power supply device
Is provided with a diode 203A and a capacitor 203B. The conversion circuit 203 rectifies and smoothes the AC voltage from the secondary side of the transformer 201. The DC voltage from the capacitor 203B is applied between the terminal 213 and the ground terminal 215. This DC voltage is one of the DC outputs generated by the switching power supply device.

Detection circuit 207 of the switching power supply device
But has resistors 207A and 207B and a shunt regulator 207C. The detection circuit 207 is a conversion circuit 20.
Change in DC voltage from 3 is detected.

Sending circuit 208 of the switching power supply device
But the photodiode 208A and the phototransistor 2
08B. The sending circuit 208 transmits the change in the DC voltage detected by the detecting circuit 207 to the controller 202B. The controller 202B stabilizes the DC voltage at the terminal 213 based on the detection signal from the sending circuit 208.

On the other hand, the diode 204 of the switching power supply device rectifies the AC voltage from the transformer 201.
The three-terminal circuit 205 converts the output from the diode 204 into a voltage having a predetermined value. The three-terminal circuit 205 internally includes a regulator circuit including a plurality of semiconductor elements such as a transistor for a regulator (not shown). The three-terminal circuit 205 applies a voltage having a predetermined value as a remote voltage between the terminal 214 and the ground terminal 215. The remote voltage is one of the DC outputs generated by the switching power supply.

The switch circuit 206 connected to the three-terminal circuit 205 controls whether or not the remote voltage is output from the three-terminal circuit 205. This switch 206
It is opened and closed by a remote signal from another circuit (not shown) attached to the switching power supply. This allows
The ground terminal 205A of the three-terminal circuit 205 is connected to or not connected to the ground terminal 215 of the switching power supply device. That is, the switching power supply device has the functions of remote on and remote off.

In this way, the conventional switching power supply device outputs the DC voltage to the terminal 213 and the remote voltage to the terminal 214.

[0010]

By the way, in the conventional switching power supply device, the detection circuit 207 and the sending circuit 208 are provided.
The DC voltage at the terminal 213 is stabilized by the control system constituted by. In addition, the three-terminal circuit 205 and the switch circuit 20
The control system constituted by 6 stabilizes the remote voltage at the terminal 214.

That is, the conventional switching power supply device has a problem that two control systems are required. This limits the miniaturization of the device circuitry and reduces efficiency.

An object of the present invention is to provide a switching power supply device capable of simplifying the circuit configuration of the device except for such problems.

[0013]

In order to achieve the object, the present invention provides a switching circuit for intermittently converting a direct current applied to a primary side of a transformer and converting the direct current into an alternating current, and a first secondary circuit of the transformer. A conversion circuit that converts alternating current from the secondary side to direct current and outputs this direct current as the first output, a rectifying circuit that rectifies alternating current from the second secondary side of the transformer, and a first smoothing that smoothes the rectified output. A circuit, a switch circuit that makes the output from the rectifier circuit either conductive or non-conductive by an input remote signal, and a second smoothing circuit that smoothes the output from the switch circuit to a second output A detection circuit for detecting a change in direct current applied to this terminal; a transmission circuit for transmitting a detection signal from the detection circuit to the switching circuit; and a rectification circuit and a first circuit when the switch circuit is in a conducting state. The connection of the smoothing circuit is released, the second output from the second smoothing circuit is added to the detection terminal of the detecting circuit, and when the switch circuit is in the non-conducting state, the rectifying circuit is connected to the first smoothing circuit and the second smoothing circuit is connected. A switching circuit that disconnects the circuit and the detection terminal and adds the output of the first smoothing circuit to the detection terminal is provided, and the switching circuit changes the intermittent period based on the detection signal from the transmission circuit to output the output. It is characterized by stabilizing.

With this configuration, when the switch circuit is in the conducting state, the switching circuit disconnects the rectifying circuit and the first smoothing circuit. At the same time, the switching circuit applies the second output from the second smoothing circuit to the detection terminal of the detection circuit. As a result, the detection circuit outputs the detection signal indicating the change in the second output,
It is sent to the switching circuit via the transmission circuit. As a result, the switching circuit changes the period of intermittent DC so as to stabilize the second output.

Further, when the switch circuit is in the non-conducting state, the switching circuit connects the rectifier circuit to the first smoothing circuit. At the same time, the switching circuit disconnects the connection between the second smoothing circuit and the detection terminal and applies the output of the first smoothing circuit to the detection terminal.

In this state, if the first output changes due to a change in the load, this change affects the output on the second secondary side of the transformer. Direct current obtained by rectifying and smoothing the output of the second secondary side of the transformer is applied to the detection terminal of the detection circuit. Therefore, the detection circuit detects the change in the first output and sends it to the switching circuit. As a result, the switching circuit changes the intermittent period so as to stabilize the first output.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of the present invention will be described.
This will be described with reference to the drawings.

FIG. 1 is a diagram showing a switching power supply device according to an embodiment of the present invention. This switching power supply device includes a transformer 1, a switching circuit 2, a conversion circuit 3, a diode 4 as a rectifying circuit, a capacitor 5 as a first smoothing circuit, a switch circuit 6, and a capacitor 7 as a second smoothing circuit. Detection circuit 8 and transmission circuit 9
And a switching circuit 10.

In the switching power supply device according to this embodiment, the switching circuit 2 is provided with the MOS.FET 2A and the controller 2B, and the conversion circuit 3 is provided with the diode 3
A and a capacitor 3B are provided. In addition, the switch circuit 6
Includes a MOS • FET 6A and a resistor 6B, and the detection circuit 8 includes resistors 8A and 8B and a shunt regulator 8C. Further, the transmission circuit 9 includes a photodiode 9A and a phototransistor 9B, and the switching circuit 10 includes diodes 10A and 10B.

The transformer 1 has a primary side and two secondary sides. On the primary side of the transformer 1, a terminal 101 and a MOS
The FET 2A is connected. The conversion circuit 3 and the ground terminal 105 are connected to one secondary side (first secondary side), and the diode 4 is connected to the other secondary side (second secondary side).
Is connected to the ground terminal 105. And the first
The secondary side outputs a higher AC voltage than the second secondary side.

The switching circuit 2 is an n-channel MO
It is provided with an S-FET 2A and a controller 2B. further,
As shown in FIG. 2, the controller 2B includes an output voltage control circuit 21 and a gate drive circuit 22.

Output voltage control circuit 2 of switching circuit 2
1 receives the detection signal generated by the phototransistor 9B of the transmission circuit 9. The output voltage control circuit 21 generates a control signal whose voltage changes according to the current change of the detection signal. The output voltage control circuit 21 outputs this control signal to the gate drive circuit 22. Upon receiving the control signal from the output voltage control circuit 21, the gate drive circuit 22 controls the gate voltage applied to the MOS • FET 2A based on the control signal, and changes the intermittent cycle of the MOS • FET 2A.

MOS FET2A of the switching circuit 2
Under the control of the controller 2B, the DC current flowing from the terminal 101 to the terminal 102 is interrupted via the primary side of the transformer 1 to apply a pulsed AC voltage to the primary side of the transformer 1.

The diode 3A of the conversion circuit 3 is connected as follows. The anode of the diode 3A is connected to the first secondary side of the transformer 1, and the cathode of the diode 3A is connected to the terminal 103.
It is connected to the. With such a connection, the diode 3A rectifies the AC voltage output from the first secondary side of the transformer 1.

The capacitor 3B of the conversion circuit 3 has a terminal 10
3 and the ground terminal 105. With such a connection, the capacitor 3B smoothes the voltage rectified by the diode 3A and converts it into a DC voltage. Then, the capacitor 3B outputs this DC voltage to the terminal 103.

The diode 4 is connected as follows. The anode of the diode 4 is connected to the second secondary side of the transformer 1, and the cathode is connected to the MOS • FET 6A. With such a connection, the diode 4 rectifies the AC voltage output from the second secondary side of the transformer 1.

The capacitor 5 is connected in series with the diode 10A. With such a connection, the capacitor 5 smoothes the voltage applied via the diode 10A and converts it into a DC voltage.

The MOS • FET 6A of the switch circuit 6 is
They are connected as follows: MOS of switch circuit 6
The drain of the FET 6A is connected to the cathode of the diode 4, and the source is connected to the terminal 104. Also, M
The gate of the OS • FET 6A is connected to the remote terminal 106. Further, one end of the resistor 6B is connected to the gate of the MOS • FET 6A. The other end of the resistor 6B is connected to the terminal 103.

With such a connection, the remote terminal 10
If 6 does not receive the remote signal, MOS-FET6
A has a conductive state (hereinafter, referred to as ON) between the drain and the source due to the resistor 6B. The saturation voltage at this time is V
It is _SAT . Further, when the remote terminal 106 receives a remote signal of “L (low)” level, the MOS · F
The drain and the source of the ET6A are brought into a non-conductive state (hereinafter referred to as OFF).

The capacitor 7 is connected between the terminal 104 and the ground terminal 105. By such a connection, the capacitor 7 smoothes the voltage from the MOS • FET 6A, and the smoothed voltage is used as the remote voltage, and the terminal 10
4 is output.

The resistor 8A of the detection circuit 8 is connected in series with the resistor 8B. This series circuit includes a detection circuit 8
Is connected between the detection terminal 8D and the ground terminal 105. With such a connection, the resistors 8A and 8B divide the remote voltage applied via the diode 10B and apply it to the shunt regulator 8C.

Shunt regulator 8C of detection circuit 8
Are connected as follows: The shunt regulator 8C is connected in series to the photodiode 9A of the transmission circuit 9. And the shunt regulator 8
The C causes a current proportional to the remote voltage to flow through the transmission circuit 9 by the divided voltage generated by the resistors 8A and 8B.

The transmission circuit 9 is a photocoupler in which the photodiode 9A and the phototransistor 9B are integrated.

The photodiode 9A of the transmission circuit 9 is connected in series with the shunt regulator 8C. Further, this series circuit is connected between the terminal 103 and the ground terminal 105. With such a connection, the current generated by the shunt regulator 8C flows through the photodiode 9A. That is, a current proportional to the remote voltage flows through the photodiode 9A. The photodiode 9A generates light according to this current.

The phototransistor 9B of the transmission circuit 9 is
They are connected as follows: The collector of the phototransistor 9B is connected to the controller 2B, and the emitter is connected to the terminal 102. With such a connection, the phototransistor 9B receives the light from the photodiode 9A. Then, the phototransistor 9B sends a current proportional to the received light to the controller 2B as a detection signal.

The diode 10A of the switching circuit 10 is connected as follows. The cathode of the diode 10A is connected to the capacitor 5, and the diode 10A is connected to the capacitor 5 in series. This series circuit is connected between the cathode of the diode 4 and the ground terminal 105. The anode of the diode 10B is connected to the terminal 104, and the cathode is connected to the detection terminal 8D of the detection circuit 8. Furthermore, the diode 10
A connection point 107 between A and the capacitor 5 is connected to the detection terminal 8D of the detection circuit 8.

Diodes 10A and 10 of the switching circuit 10
The forward voltages V _F1 and V _F2 of B are forward voltage V _F1 ≧ saturation voltage V _{SAT with} respect to the saturation voltage V _SAT of the MOS • FET 6A.
It is set as + forward voltage V _F2 .

As a result, when the MOS • FET 6A is on, the voltage drop due to the diode 10A is
Since the voltage drop due to the FET 6A and the diode 10B is large, the diode 10A is turned off and the diode 10B is turned on. On the contrary, MOS ・ FET6
When A is off, diode 10A is on,
The diode 10B is turned off. In other words, MOS / FE
The states of the diodes 10A and 10B are as follows depending on the state of T6A.

[0039]

[Table 1] Next, the operation of this embodiment will be described.

When a DC voltage is applied between the terminals 101 and 102, the MOS.FET 2A turns into a controller 2B.
The DC voltage is interrupted at high speed under the control of. The alternating current generated by this interruption flows through the primary side of the transformer 1. As a result, an AC voltage is generated on the two secondary sides of the transformer 1.

The diode 3A rectifies the AC voltage output from the first secondary side of the transformer 1, and the capacitor 3B
Converts the voltage rectified by the diode 3A into a DC voltage. The capacitor 3B outputs this DC voltage to the terminal 103. At the same time, the DC voltage of the capacitor 3B is applied to the photodiode 9A and the resistor 6B.

In such a state, the remote terminal 10
If no remote signal is applied to 6, then: At this time, the MOS • FET 6A is turned on, and the diode 4 rectifies the AC voltage from the second secondary side of the transformer 1. The rectified voltage passes through the MOS • FET 6A and is applied to the capacitor 7. The capacitor 7 is a MOS
The voltage from the FET 6A is smoothed, and the smoothed voltage is output to the terminal 104 as a remote voltage.

With this voltage, the diodes 10A ... OFF diode 10B ... ON. Thereby, the remote voltage of the terminal 104 is applied to the detection terminal 8D.

At this time, if the remote voltage fluctuates under the influence of a load, for example, the divided voltage generated by the resistors 8A and 8B also changes. Shunt regulator 8C
Converts this change in divided voltage into a change in current. This change in current is transmitted to the phototransistor 9B by the photodiode 9A. The controller 2B changes the intermittent period of the MOS • FET 2A by the detection signal of the phototransistor 9B. This stabilizes the remote voltage.

When a remote signal is applied to remote terminal 106: At this time, MOS ・ FET
6A is off. The voltage from the second secondary side of the transformer 1 is rectified by the diode 4 and smoothed by the capacitor 5. Since the connection point 107 is connected to the detection terminal 8D, the voltage of the detection terminal 8D becomes equal to the voltage of the capacitor 5. At the same time, since the MOS FET6A is off,
The diode 10B is turned off. As a result, the terminal 104
No voltage is output to. Further, the DC voltage at the connection point 107 is not affected by the load connected to the terminal 104.

On the other hand, the voltage from the first secondary side of the transformer 1 is converted into direct current by the diode 3A and the capacitor 3B and output from the terminal 103. At this time, the terminal 10
If the voltage of 3 fluctuates due to the influence of the load, for example, the fluctuation causes the voltage from the first secondary side of the transformer 1 to fluctuate. The voltage on the second secondary side of the transformer 1 fluctuates so as to be linked with this fluctuation. As a result, the DC voltage at the connection point 107 changes. This fluctuation is applied to the detection terminal 8D of the detection circuit 8. Then, the resistors 8A, 8 of the detection circuit 8
The divided voltage generated by B changes similarly. The shunt regulator 8C converts this change in divided voltage into a change in current. This change in current is caused by the photodiode 9A.
Is transmitted to the phototransistor 9B. The controller 2B uses the detection signal of the phototransistor 9B for M
Change the intermittent cycle of OS-FET2A. This allows
The DC voltage at terminal 103 is stabilized.

Thus, according to this embodiment,
With only the control system composed of the detection circuit 8 and the transmission circuit 9,
The DC voltage at the terminal 103 and the remote voltage at the terminal 104 can be stabilized. As a result, the number of control systems can be reduced as compared with the conventional case.

As a result, the efficiency can be improved. Further, the device can be downsized, and the cost of the device can be reduced.

[0049]

As described above, according to the present invention, when the switch circuit is in the conducting state, the change in the second output is detected and sent to the switching circuit, so that the second output is stabilized. Further, when the switch circuit is in the non-conducting state, the change in the first output is detected and sent to the switching circuit, so that the first output is stabilized. As a result, the output can be stabilized with one control system. As a result, the circuit configuration of the device can be simplified and the device can be downsized. In addition, efficiency can be improved.

[Brief description of drawings]

FIG. 1 is a block diagram showing a switching power supply device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a controller.

FIG. 3 is a block diagram showing a conventional switching power supply device.

[Explanation of symbols]

 1 transformer 2 switching circuit 2A MOS / FET 2B controller 3 conversion circuit 3A diode 3B capacitor 4 diode 5 capacitor 6 switch circuit 6A MOS / FET 6B resistor 7 capacitor 8 detection circuit 8A, 8B resistor 8C shunt regulator 8D detection terminal 9 transmission circuit 9A Photodiode 9B Phototransistor 10 Switching circuit 10A, 10B Diode

Claims (1)

[Claims] 1. A switching circuit for connecting and disconnecting a direct current applied to the primary side of a transformer to convert this direct current into an alternating current, and an alternating current from a first secondary side of the transformer to convert this direct current into a direct current. 1 output conversion circuit, rectification circuit that rectifies the alternating current from the second secondary side of the transformer, 1st smoothing circuit that smoothes the rectified output, output from the rectification circuit by the input remote signal Switch circuit for turning on or off the switch, and a second circuit for smoothing the output from the switch circuit to the second output
A smoothing circuit, a detection circuit that has a detection terminal that detects changes in direct current applied to this terminal, a transmission circuit that sends the detection signal from the detection circuit to the switching circuit, and a rectification circuit when the switch circuit is in the conducting state. And disconnecting the first smoothing circuit from the second smoothing circuit
The output is applied to the detection terminal of the detection circuit, and when the switch circuit is in the non-conducting state, the rectifier circuit is connected to the first smoothing circuit and the connection between the second smoothing circuit and the detection terminal is released, and the first
A switching power supply device, comprising: a switching circuit that adds the output of the smoothing circuit to a detection terminal, and the switching circuit stabilizes the output by changing the intermittent period based on the detection signal from the transmission circuit.