JPH10320081A - Power supply switching circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent supply voltage to load from dropping even instantly by simultaneously supplying outputs from both power supplies to the load when 1st and 2nd power supplies are switched and connected. SOLUTION: This circuit is provided with a 1st switching means 12 which turns on and off the output of a 1st power supply 10, a 2nd switching means 13 which turns on and off the output of a 2nd power supply 11 and a controller 100 that controls the means 12 and 13. In such cases, the controller 100 surely prevents supply voltage from dropping when power supply is switched by providing a period when both switches 12 and 13 are turned on when the power supplies 10 and 11 are performed power supply switching to the power supplies 11 and 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply switching circuit for switching and connecting two power supplies to a circuit.

[0002]

2. Description of the Related Art At present, many portable electronic devices can be used by switching at least two power sources, a commercial power source and a battery power source, in order to provide a use environment both indoors and outdoors. In an apparatus using only a power supply, two battery power supplies can be switched and used for the purpose of memory backup at the time of battery replacement and extension of operation time.

As a conventional method of switching between two power supplies, for example, Japanese Patent Laid-Open No. 6-12876 (G11C11)
As described in / 413), a general method is to provide switching means at each output terminal of two power supplies and switch the switching means to ON / OFF with one signal.

FIG. 2 is a circuit diagram showing this conventional method. The first power supply 1 and the second power supply 2 are respectively FET
Are connected to a circuit to be driven via first and second switching means 3 and 4. The output of the first power supply 1 is compared with the reference voltage Vref in the comparison circuit 5. The output of the comparison circuit 5 is directly supplied to the gate of the first switching circuit 3 and the signal inverted by the inversion circuit 6 is supplied to the gate of the second switching circuit 4.

Therefore, when the output voltage of the first power supply 1 is higher than the reference voltage Vref, the first switching means 3 is turned on and the second switching means 4 is turned off. Is supplied to the circuit. On the other hand, when the output voltage of the first power supply 1 falls below the reference voltage Vref, the first switching means 3 is turned off and the second switching means 4 is turned on. Is supplied to the circuit.

[0006]

However, in the above-mentioned conventional method, the first and second switching means 3 and 4 are not connected due to a difference in response speed between the first and second switching means 3 and 4 and the inverting circuit 6. There is a problem that a period in which both of them are off occurs instantaneously and the supply voltage to the circuit drops.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has a feature of a power supply switching circuit for switching between two power supplies and connecting to a load. In switching to another power supply, the output of the one power supply is stopped in response to the output of the other power supply.

[0008]

FIG. 1A is a circuit diagram showing an embodiment of the present invention. In the present embodiment, the first power supply 10 and the second power supply 11 are constituted by batteries.

The first power supply 10 is connected to the source terminal S of the first switch means 12 composed of an FET. Also,
The second power supply 11 is provided with a second switch 13 composed of an FET.
Is connected to the source terminal S. A gate terminal G of the first switch means 12 has a first control signal PBATTO.
The FF and the gate terminal G of the second switch means 13 are supplied with the second control signal SBATTOFF.

The first and second control signals are both supplied to the first and second power supplies 1 detected by a controller 100 (not shown).
The controller 100 based on the output voltages 0, 11
It is a signal output from Specifically, the controller 100 sets the first control signal PBATTOFF to low and sets the second control signal SBATTOFF to high when the output voltage of the first power supply 10 is equal to or higher than a predetermined value. Accordingly, only the output of the first power supply 10 can be selectively supplied. When the controller 100 detects that the output voltage of the first power supply 10 has dropped below a predetermined value and that the output voltage of the second power supply 11 has reached a predetermined value or more, the power supply is switched to the second power supply 11. In order to switch, the controller 100 temporarily sets both the first and second control signals to low to enable the supply of the voltage from the power sources 10 and 11. Then, after a predetermined time has elapsed, the first power supply 10
To the second power supply 11 is completed. When it is necessary to switch from the second power supply 11 to the first power supply 10,
That is, when the controller 100 determines that the output voltage of the second power supply 11 is equal to or lower than the predetermined voltage and the output voltage of the first power supply 10 is equal to or higher than the predetermined voltage,
0 indicates that the first and second control signals are once both low, and then the second control signal SBATTOF after a predetermined time has elapsed.
This can be done by setting F high.

The drain terminal D of the first switch means 12 is connected to the drain terminal D of the third switch means 14 comprising an FET. The gate terminal G of the third switch means 14 is connected to the drain terminal D of the second switch means 13 via the first backflow prevention diode 15. Also, the gate terminal G of the third switch means 14
Are connected to the source terminal S of the third switch means 14 and ground via the first resistor 16 and the second resistor, respectively. Further, a first bypass diode 18 is connected between the drain and the source of the third switch means 14.

Therefore, when the controller 100 determines that the switching to the second power supply 11 is necessary and makes the second control signal low, the second control means 13 and the first backflow prevention diode 15 The output voltage of the second power supply 11 is supplied to the gate terminal G of the third switch means 14, and the gate terminal G of the third switch means 14
Since the side voltage is higher than the source terminal S side voltage, the drain-source of the third switch means 14 is in a non-conductive state (OFF).

The drain terminal D of the second switch means 13 is connected to the drain terminal D of the fourth switch means 19 comprising an FET. The gate terminal G of the fourth switch 19 is connected to the drain terminal D of the first switch 12 via the second backflow prevention diode 20. Also, the gate terminal G of the fourth switch means 19
Is connected to the source terminal S of the fourth switch means 19 and the ground via a third resistor 21 and a fourth resistor 22, respectively. Further, a second bypass diode 23 is connected between the drain and the source of the fourth switch 19.

Accordingly, when the controller 100 determines that switching to the first power supply 10 is necessary and sets the first control signal to low, the controller 100 controls the first power supply 10 via the first switch means 12 and the second backflow prevention diode 20. The output voltage of the first power supply 10 is supplied to the gate terminal G of the fourth switch means 19, and the gate terminal G of the fourth switch means 19 is supplied.
Since the side voltage is higher than the source terminal S side voltage, the drain-source of the fourth switch 19 is in a non-conductive state (OFF).

The first and second bypass diodes 1
As will become clear from the description below, the output voltages 8 and 23 can supply the output voltages of the first and second power supplies 10 and 11 to the load even when the third and fourth switch means 14 and 19 are both turned off. A bypass for Further, a fifth resistor 24 connected between the drain terminal D of the second switch means 13 and the ground and a sixth resistor 25 connected between the drain terminal D of the first switch means 12 and the ground are each a second resistor. A minute leak current between the source and the drain of the switch means 13 or the first switch means 12 is dropped to ground,
This is to prevent the adverse effect of the current.

Next, the operation of the circuit of this embodiment will be described with reference to the timing chart shown in FIG.

When the output voltage of the first power supply 10 is equal to or higher than the value (the above-mentioned predetermined value) sufficient to drive the load, the controller 100 outputs the output of the first power supply 10 to the drive voltage. 1B, the first control signal PBATTOFF is set low and the second control signal SBATTOFF is set high as shown in a period T1 in FIG. As a result, the source-drain of the first switch means 12 becomes conductive (on), and the source-drain of the second switch means 13 becomes non-conductive (off). Also,
The output voltage of the first power supply 10 is supplied to the gate terminal G of the fourth switch means 19 in accordance with the on / off state of the first and second switch means 12 and 13. Since the output voltage of the second power supply 11 is not supplied to G, the drain-source of the third switch 14 is conductive (on) during the period T1 and the drain-source of the fourth switch 19 is connected. It becomes a non-conductive state (OFF). As a result, the first power supply 1
An output voltage of 0 is supplied via the first and third switch means 12 and 14.

Further, the controller 100 determines that the output voltage of the first power supply 10 has dropped to a predetermined value or less, and
When detecting that the output voltage of the power supply 11 is equal to or higher than the predetermined value, the controller 100 first changes the second control signal SBATTOFF from high to low in order to switch the power supply from the first power supply 10 to the second power supply 11. The first control signal PBATTOFF is changed from low to high after a predetermined time has elapsed (period T2 in FIG. 1B). When the second control signal SBATTOFF is changed from high to low, the source-drain of the second switch means 13 becomes conductive (on), and accordingly, the gate terminal G of the third switch means 14 is connected to the second terminal. Since the output voltage of the power supply 11 is supplied, the state between the drain and the source of the third switch means 14 is also in a non-conductive state (OFF) as in the fourth switch means 19. Thus, the third and fourth switch means 14,
When both 19 are turned off, it becomes impossible to supply voltage to the load via this switch means, but the first and second bypasses are provided between the drain and source of the third and fourth switch means 14 and 19, respectively. Since the diodes 18 and 23 are connected in parallel, the output voltages of the first and second power supplies 10 and 11 can be supplied to the load via the diodes.

The first and second switch means 1
The reason why the period T2 in which both the second and the third switch 13 are on is provided is that the first and second switch means 12 and 13 are simultaneously changed from on to off and from off to on as described above as a conventional problem. In this case, a period in which the first and second switching means are both turned off due to a difference in response speed or the like occurs to prevent the supply voltage to the circuit from instantaneously dropping and causing a malfunction. is there. Therefore, the period T
2 may be longer than the delay time caused by the response speed of each switch means, and may be substantially several microseconds or longer.

At the end of the period T2, the first control signal P
When BATTOFF goes high, the first switch 12
Is turned off, and the supply of the output voltage of the first power supply 10 to the gate terminal G of the fourth switch means 19 is stopped. Accordingly, the drain-source of the fourth switch 19 becomes conductive (on), Only the output voltage of the second power supply 11 is supplied to the load via the second and fourth switch means 13 and 19.

[0021]

As described above, according to the present invention, when switching between the first power supply and the second power supply, the outputs from both power supplies are simultaneously supplied to the load. In particular, it is possible to prevent the supply voltage to the load from dropping. Further, in this power supply switching, the output of the power supply used so far is turned off based on the reliable rise of the power supply to be switched, so that a drop in the supply voltage to the load can be prevented more reliably.

[Brief description of the drawings]

FIG. 1 is a circuit diagram (a) and a timing chart (b) showing an embodiment of the present invention.

FIG. 2 is a circuit diagram showing a conventional example.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 1st power supply 11 2nd power supply 12 1st switch means 13 2nd switch means 14 3rd switch means 18 1st bypass diode 19 4th switch means 23 2nd bypass diode 24 5th resistance 25 6th resistance 100 Controller

Claims (8)

[Claims] 1. A power supply switching circuit for switching between two power supplies and connecting the load to a load, wherein when switching from one power supply to another power supply, the one power supply responds to an output of the other power supply. A power supply switching circuit for stopping output. 2. A power supply switching circuit for switching between a first power supply and a second power supply and connecting to a load, wherein a first switch means for turning on and off an output of the first power supply. A second switch for turning on / off the output of the second power supply; and a controller for controlling each of the switch means. A power supply switching circuit characterized by providing a period for turning on both the first and second switches when the power supply is switched to the first power supply. 3. The power supply switching circuit according to claim 2, further comprising: supplying the output of the first power supply output via the first switch means to the load to the second switch means. A third switch for controlling based on the presence or absence of the output of the second power supply output via the second power supply; and an output of the second power supply output via the second switch means to the load. Third switch means for controlling supply based on the presence or absence of the output of the first power supply output via the first switch means, and the first power supply output via the first switch means A first bypass means for allowing the output of the second power supply to be supplied to the load by bypassing the third switch means, and an output of the second power supply outputted via the second switch means to the third bypass means. By bypassing the switch means A power supply switching circuit comprising: a second bypass unit that can supply a load. 4. The power supply switching circuit according to claim 2, wherein said period is at least a delay time generated based on a response speed of said switch means. 5. A first power supply 10, a second power supply 11, and a first power supply.
The first switch means 12 connected to the power supply 10, the second switch means 13 connected to the second power supply 11, and a second switch means 13 for selectively switching and outputting the outputs of the first power supply 10 and the second power supply 11. The controller 100 controls on / off of the first and second switch means 12 and 13, and supplies the output of the first power supply 10 output via the first switch means 12 to the load via the second switch means 13. Switch means 14 for controlling based on the presence or absence of the output of all the second power supplies 11
And a fourth switch for controlling the supply of the output of the second power supply 11 output via the second switch means 13 to the load based on the presence or absence of the output of the first power supply 10 via the first switch means 12. Power supply switching circuit, comprising: a first bypass means connected in parallel with the third switch means; and a second bypass means connected in parallel with the fourth switch means. . 6. Each of the switch means 12, 13, according to claim 5,
14 and 19 are constituted by FETs, the first and second bypass means 18 and 23 are constituted by diodes, the source terminal S of the first switch means 12 is connected to the first power supply 10, and the drain terminal D is The drain terminal D of the third switch means 14 and the gate terminal G of the fourth switch means 19 are connected, the gate terminal G is connected to the controller 100, and the source terminal S of the second switch means 13 is connected to the second power supply 1
1 and the drain terminal D is connected to the fourth switch means 19
Is connected to the drain terminal D and the gate terminal G of the third switch means 14, the gate terminal G is connected to the controller 100, and resistors 16 and 21 are connected between the source and gate of the third and fourth switch means 14 and 19. A power supply switching circuit, which is connected via a power supply. 7. The power supply switching circuit according to claim 6, wherein the drain terminals D of the first and second switch means are grounded via resistors 25 and 24, respectively. 8. The power supply switching circuit according to claim 2, wherein
A power supply switching circuit, wherein the controller detects output voltages of the first and second power supplies and controls on / off of first and second switch means based on the detection results.